Quizbank/Electricity and Magnetism (calculus based)/c12

calcPhyEMq/c12 ID153287923206 (|Study guide)

Exams:  A0  A1  A2   B0  B1  B2   C0  C1  C2   D0  D1  D2   E0  E1  E2   F0  F1  F2   G0  G1  G2   H0  H1  H2   I0  I1  I2   J0  J1  J2   K0  K1  K2   L0  L1  L2   M0  M1  M2   N0  N1  N2   O0  O1  O2   P0  P1  P2   Q0  Q1  Q2   R0  R1  R2   S0  S1  S2   T0  T1  T2   U0  U1  U2   V0  V1  V2   W0  W1  W2   X0  X1  X2   Y0  Y1  Y2   Z0  Z1  Z2

Answers:  A0  A1  A2   B0  B1  B2   C0  C1  C2   D0  D1  D2   E0  E1  E2   F0  F1  F2   G0  G1  G2   H0  H1  H2   I0  I1  I2   J0  J1  J2   K0  K1  K2   L0  L1  L2   M0  M1  M2   N0  N1  N2   O0  O1  O2   P0  P1  P2   Q0  Q1  Q2   R0  R1  R2   S0  S1  S2   T0  T1  T2   U0  U1  U2   V0  V1  V2   W0  W1  W2   X0  X1  X2   Y0  Y1  Y2   Z0  Z1  Z2

78 Tests = 3 versions x 26 variations: Each of the 26 variations (A, B, ...) represents a different random selection of questions taken from the |study guide.The 3 versions (0,1,..) all have the same questions but in different order and with different numerical inputs. Unless all students take  version "0" it is best to reserve it for the instructor because the questions are grouped according to the order in which they appear on the study guide.

Links:  Quizbank/Instructions   |Study guide    file:Quizbank153287923206.pdf

Contact me at User talk:Guy vandegrift if you need any help.

c12 A0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.277E+05 A
 * b) 3.604E+05 A
 * c) 3.965E+05 A
 * d) 4.361E+05 A
 * e) 4.797E+05 A

2) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * a) 7.952E-03 T
 * b) 8.747E-03 T
 * c) 9.622E-03 T
 * d) 1.058E-02 T
 * e) 1.164E-02 T

3) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * a) 5.926E-11 N/m
 * b) 6.518E-11 N/m
 * c) 7.170E-11 N/m
 * d) 7.887E-11 N/m
 * e) 8.676E-11 N/m

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 1.791E-05 T
 * b) 1.970E-05 T
 * c) 2.167E-05 T
 * d) 2.384E-05 T
 * e) 2.622E-05 T

c12 A1
1) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * a) 1.422E-11 N/m
 * b) 1.564E-11 N/m
 * c) 1.720E-11 N/m
 * d) 1.892E-11 N/m
 * e) 2.081E-11 N/m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 1.791E-05 T
 * b) 1.970E-05 T
 * c) 2.167E-05 T
 * d) 2.384E-05 T
 * e) 2.622E-05 T

3) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * a) 4.799E-02 T
 * b) 5.278E-02 T
 * c) 5.806E-02 T
 * d) 6.387E-02 T
 * e) 7.026E-02 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.871 m and $$B_{max}=\,$$ 0.427 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.688 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.404E+06 A
 * b) 1.544E+06 A
 * c) 1.699E+06 A
 * d) 1.869E+06 A
 * e) 2.056E+06 A

c12 A2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.208E-05 T
 * b) 1.329E-05 T
 * c) 1.462E-05 T
 * d) 1.608E-05 T
 * e) 1.769E-05 T

2) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * a) 2.977E-11 N/m
 * b) 3.274E-11 N/m
 * c) 3.602E-11 N/m
 * d) 3.962E-11 N/m
 * e) 4.358E-11 N/m

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.645 m and $$B_{max}=\,$$ 0.469 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.26 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.949E+05 A
 * b) 3.244E+05 A
 * c) 3.568E+05 A
 * d) 3.925E+05 A
 * e) 4.317E+05 A

4) Two loops of wire carry the same current of 88 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.655 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.531 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * a) 4.162E-02 T
 * b) 4.578E-02 T
 * c) 5.036E-02 T
 * d) 5.540E-02 T
 * e) 6.094E-02 T

c12 B0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.571 m and $$B_{max}=\,$$ 0.331 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.321 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.226E+05 A
 * b) 3.549E+05 A
 * c) 3.904E+05 A
 * d) 4.294E+05 A
 * e) 4.724E+05 A

2) Two parallel wires each carry a 2.12 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.67 cm, 1.25 cm), while the other is located at (4.69 cm, 4.27 cm). What is the force per unit length between the wires?


 * a) 2.119E-11 N/m
 * b) 2.331E-11 N/m
 * c) 2.564E-11 N/m
 * d) 2.820E-11 N/m
 * e) 3.102E-11 N/m

3) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.545E-05 T
 * b) Bx= 7.200E-05 T
 * c) Bx= 7.919E-05 T
 * d) Bx= 8.711E-05 T
 * e) Bx= 9.583E-05 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 3.416E-05 T
 * b) 3.758E-05 T
 * c) 4.133E-05 T
 * d) 4.547E-05 T
 * e) 5.001E-05 T

c12 B1
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.66 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.935E-05 T
 * b) 2.128E-05 T
 * c) 2.341E-05 T
 * d) 2.575E-05 T
 * e) 2.832E-05 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 7.876E+05 A
 * b) 8.664E+05 A
 * c) 9.530E+05 A
 * d) 1.048E+06 A
 * e) 1.153E+06 A

3) Two parallel wires each carry a 7.48 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.13 cm, 0.955 cm), while the other is located at (5.37 cm, 5.48 cm). What is the force per unit length between the wires?


 * a) 2.015E-10 N/m
 * b) 2.216E-10 N/m
 * c) 2.438E-10 N/m
 * d) 2.682E-10 N/m
 * e) 2.950E-10 N/m

4) Three wires sit at the corners of a square of length 0.51 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.16 A, 2.46 A, 2.15 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 9.053E-05 T
 * b) Bx= 9.959E-05 T
 * c) Bx= 1.095E-04 T
 * d) Bx= 1.205E-04 T
 * e) Bx= 1.325E-04 T

c12 B2
1) Three wires sit at the corners of a square of length 0.466 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.4 A, 2.42 A, 1.9 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 1.335E-04 T
 * b) Bx= 1.468E-04 T
 * c) Bx= 1.615E-04 T
 * d) Bx= 1.777E-04 T
 * e) Bx= 1.954E-04 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.382E+05 A
 * b) 3.720E+05 A
 * c) 4.092E+05 A
 * d) 4.502E+05 A
 * e) 4.952E+05 A

3) Two parallel wires each carry a 3.51 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.14 cm, 1.43 cm), while the other is located at (4.14 cm, 5.23 cm). What is the force per unit length between the wires?


 * a) 6.484E-11 N/m
 * b) 7.133E-11 N/m
 * c) 7.846E-11 N/m
 * d) 8.631E-11 N/m
 * e) 9.494E-11 N/m

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.66 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.935E-05 T
 * b) 2.128E-05 T
 * c) 2.341E-05 T
 * d) 2.575E-05 T
 * e) 2.832E-05 T

c12 C0
1) Three wires sit at the corners of a square of length 0.76 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.91 A, 1.34 A, 1.05 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 5.611E-05 T
 * b) By= 6.172E-05 T
 * c) By= 6.789E-05 T
 * d) By= 7.468E-05 T
 * e) By= 8.215E-05 T

2) Three wires sit at the corners of a square of length 0.466 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.4 A, 2.42 A, 1.9 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 1.335E-04 T
 * b) Bx= 1.468E-04 T
 * c) Bx= 1.615E-04 T
 * d) Bx= 1.777E-04 T
 * e) Bx= 1.954E-04 T

3) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.034E+00 Tesla
 * b) 5.538E+00 Tesla
 * c) 6.091E+00 Tesla
 * d) 6.701E+00 Tesla
 * e) 7.371E+00 Tesla

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.59 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 2.072E-05 T
 * b) 2.279E-05 T
 * c) 2.507E-05 T
 * d) 2.758E-05 T
 * e) 3.034E-05 T

c12 C1
1) A wire carries a current of 269 A in a circular arc with radius 2.35 cm swept through 36 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 1.613E+00 Tesla
 * b) 1.774E+00 Tesla
 * c) 1.951E+00 Tesla
 * d) 2.146E+00 Tesla
 * e) 2.361E+00 Tesla

2) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.518E-05 T
 * b) By= 8.270E-05 T
 * c) By= 9.097E-05 T
 * d) By= 1.001E-04 T
 * e) By= 1.101E-04 T

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 3.324E-05 T
 * b) 3.657E-05 T
 * c) 4.022E-05 T
 * d) 4.424E-05 T
 * e) 4.867E-05 T

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.545E-05 T
 * b) Bx= 7.200E-05 T
 * c) Bx= 7.919E-05 T
 * d) Bx= 8.711E-05 T
 * e) Bx= 9.583E-05 T

c12 C2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 1.791E-05 T
 * b) 1.970E-05 T
 * c) 2.167E-05 T
 * d) 2.384E-05 T
 * e) 2.622E-05 T

2) Three wires sit at the corners of a square of length 0.64 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.76 A, 1.02 A, 1.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 3.394E-05 T
 * b) Bx= 3.733E-05 T
 * c) Bx= 4.106E-05 T
 * d) Bx= 4.517E-05 T
 * e) Bx= 4.969E-05 T

3) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.576E-05 T
 * b) By= 8.333E-05 T
 * c) By= 9.167E-05 T
 * d) By= 1.008E-04 T
 * e) By= 1.109E-04 T

4) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.498E+00 Tesla
 * b) 3.848E+00 Tesla
 * c) 4.233E+00 Tesla
 * d) 4.656E+00 Tesla
 * e) 5.122E+00 Tesla

c12 D0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.81 kA, I2=1.2 kA, and I3=1.84 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.583E-03 T-m
 * b) 3.941E-03 T-m
 * c) 4.335E-03 T-m
 * d) 4.769E-03 T-m
 * e) 5.246E-03 T-m

2) Two loops of wire carry the same current of 21 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.753 m while the other has a radius of 1.47 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.406 m from the first (smaller) loopif the disance between the loops is 1.38 m?


 * a) 1.559E-02 T
 * b) 1.715E-02 T
 * c) 1.886E-02 T
 * d) 2.075E-02 T
 * e) 2.283E-02 T

3) A wire carries a current of 106 A in a circular arc with radius 1.32 cm swept through 38 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 1.589E+00 Tesla
 * b) 1.748E+00 Tesla
 * c) 1.923E+00 Tesla
 * d) 2.116E+00 Tesla
 * e) 2.327E+00 Tesla

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.277E+05 A
 * b) 3.604E+05 A
 * c) 3.965E+05 A
 * d) 4.361E+05 A
 * e) 4.797E+05 A

c12 D1
1) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.711E+00 Tesla
 * b) 6.283E+00 Tesla
 * c) 6.911E+00 Tesla
 * d) 7.602E+00 Tesla
 * e) 8.362E+00 Tesla

2) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * a) 1.127E-02 T
 * b) 1.240E-02 T
 * c) 1.364E-02 T
 * d) 1.500E-02 T
 * e) 1.650E-02 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.78 kA, I2=2.61 kA, and I3=3.76 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.939E-03 T-m
 * b) 5.432E-03 T-m
 * c) 5.976E-03 T-m
 * d) 6.573E-03 T-m
 * e) 7.231E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.248 m and $$B_{max}=\,$$ 0.459 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.152 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.228E+05 A
 * b) 2.451E+05 A
 * c) 2.696E+05 A
 * d) 2.966E+05 A
 * e) 3.262E+05 A

c12 D2
1) Two loops of wire carry the same current of 24 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.53 m while the other has a radius of 1.38 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.485 m from the first (smaller) loopif the disance between the loops is 1.78 m?


 * a) 1.294E-02 T
 * b) 1.424E-02 T
 * c) 1.566E-02 T
 * d) 1.723E-02 T
 * e) 1.895E-02 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 5.255E-03 T-m
 * b) 5.781E-03 T-m
 * c) 6.359E-03 T-m
 * d) 6.994E-03 T-m
 * e) 7.694E-03 T-m

3) A wire carries a current of 297 A in a circular arc with radius 2.31 cm swept through 75 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.774E+00 Tesla
 * b) 4.151E+00 Tesla
 * c) 4.566E+00 Tesla
 * d) 5.023E+00 Tesla
 * e) 5.525E+00 Tesla

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.407 m and $$B_{max}=\,$$ 0.605 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.583E+05 A
 * b) 3.941E+05 A
 * c) 4.335E+05 A
 * d) 4.769E+05 A
 * e) 5.246E+05 A

c12 E0
1) Three wires sit at the corners of a square of length 0.819 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.01 A, 1.09 A, 1.56 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.688E-05 T
 * b) By= 5.156E-05 T
 * c) By= 5.672E-05 T
 * d) By= 6.239E-05 T
 * e) By= 6.863E-05 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.770E-03 T-m
 * b) 4.147E-03 T-m
 * c) 4.562E-03 T-m
 * d) 5.018E-03 T-m
 * e) 5.520E-03 T-m

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.03 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 1.720E-05 T
 * b) 1.892E-05 T
 * c) 2.081E-05 T
 * d) 2.289E-05 T
 * e) 2.518E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 16 turns per centimeter and the current applied to the solenoid is 536 mA, the net magnetic field is measured to be 1.47 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 9.310E+02
 * b) $$\chi \text{ (chi) }=$$ 1.024E+03
 * c) $$\chi \text{ (chi) }=$$ 1.126E+03
 * d) $$\chi \text{ (chi) }=$$ 1.239E+03
 * e) $$\chi \text{ (chi) }=$$ 1.363E+03

c12 E1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=1.58 kA, and I3=4.31 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.386E-03 T-m
 * b) 4.825E-03 T-m
 * c) 5.307E-03 T-m
 * d) 5.838E-03 T-m
 * e) 6.421E-03 T-m

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 17 turns per centimeter and the current applied to the solenoid is 455 mA, the net magnetic field is measured to be 1.14 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 8.804E+02
 * b) $$\chi \text{ (chi) }=$$ 9.685E+02
 * c) $$\chi \text{ (chi) }=$$ 1.065E+03
 * d) $$\chi \text{ (chi) }=$$ 1.172E+03
 * e) $$\chi \text{ (chi) }=$$ 1.289E+03

3) Three wires sit at the corners of a square of length 0.495 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.45 A, 1.66 A, 1.63 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 1.205E-04 T
 * b) By= 1.325E-04 T
 * c) By= 1.458E-04 T
 * d) By= 1.604E-04 T
 * e) By= 1.764E-04 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.488E-05 T
 * b) 1.637E-05 T
 * c) 1.800E-05 T
 * d) 1.981E-05 T
 * e) 2.179E-05 T

c12 E2
1) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.028E-05 T
 * b) By= 4.431E-05 T
 * c) By= 4.874E-05 T
 * d) By= 5.361E-05 T
 * e) By= 5.897E-05 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.354E-03 T-m
 * b) 4.789E-03 T-m
 * c) 5.268E-03 T-m
 * d) 5.795E-03 T-m
 * e) 6.374E-03 T-m

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.43 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.944E-05 T
 * b) 2.138E-05 T
 * c) 2.352E-05 T
 * d) 2.587E-05 T
 * e) 2.846E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 24 turns per centimeter and the current applied to the solenoid is 242 mA, the net magnetic field is measured to be 1.38 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.718E+03
 * b) $$\chi \text{ (chi) }=$$ 1.890E+03
 * c) $$\chi \text{ (chi) }=$$ 2.079E+03
 * d) $$\chi \text{ (chi) }=$$ 2.287E+03
 * e) $$\chi \text{ (chi) }=$$ 2.515E+03

c12 F0
1) A solenoid has 4.380E+04 turns wound around a cylinder of diameter 1.77 cm and length 16 m. The current through the coils is 0.916 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.39 cm to z=+4.26 cm


 * a) 2.478E-04 T-m
 * b) 2.726E-04 T-m
 * c) 2.998E-04 T-m
 * d) 3.298E-04 T-m
 * e) 3.628E-04 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.259 m and $$B_{max}=\,$$ 0.575 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.191 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.492E+05 A
 * b) 3.841E+05 A
 * c) 4.225E+05 A
 * d) 4.648E+05 A
 * e) 5.113E+05 A

3) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 16 turns per centimeter and the current applied to the solenoid is 536 mA, the net magnetic field is measured to be 1.47 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 9.310E+02
 * b) $$\chi \text{ (chi) }=$$ 1.024E+03
 * c) $$\chi \text{ (chi) }=$$ 1.126E+03
 * d) $$\chi \text{ (chi) }=$$ 1.239E+03
 * e) $$\chi \text{ (chi) }=$$ 1.363E+03

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.545E-05 T
 * b) Bx= 7.200E-05 T
 * c) Bx= 7.919E-05 T
 * d) Bx= 8.711E-05 T
 * e) Bx= 9.583E-05 T

c12 F1
1) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 22 turns per centimeter and the current applied to the solenoid is 568 mA, the net magnetic field is measured to be 1.29 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 8.205E+02
 * b) $$\chi \text{ (chi) }=$$ 9.026E+02
 * c) $$\chi \text{ (chi) }=$$ 9.928E+02
 * d) $$\chi \text{ (chi) }=$$ 1.092E+03
 * e) $$\chi \text{ (chi) }=$$ 1.201E+03

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.253 m and $$B_{max}=\,$$ 0.489 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.112 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.289E+05 A
 * b) 1.418E+05 A
 * c) 1.560E+05 A
 * d) 1.716E+05 A
 * e) 1.888E+05 A

3) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T

4) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * a) 6.807E-05 T-m
 * b) 7.487E-05 T-m
 * c) 8.236E-05 T-m
 * d) 9.060E-05 T-m
 * e) 9.966E-05 T-m

c12 F2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.51 m and $$B_{max}=\,$$ 0.649 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.376 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 9.388E+05 A
 * b) 1.033E+06 A
 * c) 1.136E+06 A
 * d) 1.249E+06 A
 * e) 1.374E+06 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 27 turns per centimeter and the current applied to the solenoid is 280 mA, the net magnetic field is measured to be 1.13 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.188E+03
 * b) $$\chi \text{ (chi) }=$$ 1.307E+03
 * c) $$\chi \text{ (chi) }=$$ 1.438E+03
 * d) $$\chi \text{ (chi) }=$$ 1.582E+03
 * e) $$\chi \text{ (chi) }=$$ 1.740E+03

3) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.545E-05 T
 * b) Bx= 7.200E-05 T
 * c) Bx= 7.919E-05 T
 * d) Bx= 8.711E-05 T
 * e) Bx= 9.583E-05 T

4) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * a) 1.863E-04 T-m
 * b) 2.050E-04 T-m
 * c) 2.255E-04 T-m
 * d) 2.480E-04 T-m
 * e) 2.728E-04 T-m

c12 G0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.354E-03 T-m
 * b) 4.789E-03 T-m
 * c) 5.268E-03 T-m
 * d) 5.795E-03 T-m
 * e) 6.374E-03 T-m

2) Two loops of wire carry the same current of 66 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.485 m while the other has a radius of 1.27 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.507 m from the first (smaller) loopif the disance between the loops is 1.76 m?


 * a) 2.733E-02 T
 * b) 3.007E-02 T
 * c) 3.307E-02 T
 * d) 3.638E-02 T
 * e) 4.002E-02 T

3) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * a) 6.807E-05 T-m
 * b) 7.487E-05 T-m
 * c) 8.236E-05 T-m
 * d) 9.060E-05 T-m
 * e) 9.966E-05 T-m

4) A wire carries a current of 343 A in a circular arc with radius 2.95 cm swept through 38 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 1.902E+00 Tesla
 * b) 2.092E+00 Tesla
 * c) 2.301E+00 Tesla
 * d) 2.532E+00 Tesla
 * e) 2.785E+00 Tesla

c12 G1
1) Two loops of wire carry the same current of 97 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.595 m while the other has a radius of 1.1 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.63 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * a) 5.302E-02 T
 * b) 5.832E-02 T
 * c) 6.415E-02 T
 * d) 7.056E-02 T
 * e) 7.762E-02 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.42 kA, I2=0.904 kA, and I3=1.34 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 2.696E-03 T-m
 * b) 2.966E-03 T-m
 * c) 3.263E-03 T-m
 * d) 3.589E-03 T-m
 * e) 3.948E-03 T-m

3) A wire carries a current of 293 A in a circular arc with radius 1.75 cm swept through 71 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 4.652E+00 Tesla
 * b) 5.117E+00 Tesla
 * c) 5.629E+00 Tesla
 * d) 6.192E+00 Tesla
 * e) 6.811E+00 Tesla

4) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * a) 2.176E-04 T-m
 * b) 2.393E-04 T-m
 * c) 2.633E-04 T-m
 * d) 2.896E-04 T-m
 * e) 3.186E-04 T-m

c12 G2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.72 kA, I2=2.17 kA, and I3=3.21 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.905E-03 T-m
 * b) 4.295E-03 T-m
 * c) 4.725E-03 T-m
 * d) 5.197E-03 T-m
 * e) 5.717E-03 T-m

2) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * a) 2.176E-04 T-m
 * b) 2.393E-04 T-m
 * c) 2.633E-04 T-m
 * d) 2.896E-04 T-m
 * e) 3.186E-04 T-m

3) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * a) 7.952E-03 T
 * b) 8.747E-03 T
 * c) 9.622E-03 T
 * d) 1.058E-02 T
 * e) 1.164E-02 T

4) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.034E+00 Tesla
 * b) 5.538E+00 Tesla
 * c) 6.091E+00 Tesla
 * d) 6.701E+00 Tesla
 * e) 7.371E+00 Tesla

c12 H0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.277E+05 A
 * b) 3.604E+05 A
 * c) 3.965E+05 A
 * d) 4.361E+05 A
 * e) 4.797E+05 A

2) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T

3) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 3.480E-05 T
 * b) By= 3.828E-05 T
 * c) By= 4.210E-05 T
 * d) By= 4.631E-05 T
 * e) By= 5.095E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.89 kA, I2=1.19 kA, and I3=3.5 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 6.535E-03 T-m
 * b) 7.188E-03 T-m
 * c) 7.907E-03 T-m
 * d) 8.697E-03 T-m
 * e) 9.567E-03 T-m

c12 H1
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 7.876E+05 A
 * b) 8.664E+05 A
 * c) 9.530E+05 A
 * d) 1.048E+06 A
 * e) 1.153E+06 A

2) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 3.480E-05 T
 * b) By= 3.828E-05 T
 * c) By= 4.210E-05 T
 * d) By= 4.631E-05 T
 * e) By= 5.095E-05 T

3) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 4.559E-05 T
 * b) Bx= 5.015E-05 T
 * c) Bx= 5.517E-05 T
 * d) Bx= 6.068E-05 T
 * e) Bx= 6.675E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.354E-03 T-m
 * b) 4.789E-03 T-m
 * c) 5.268E-03 T-m
 * d) 5.795E-03 T-m
 * e) 6.374E-03 T-m

c12 H2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.57 kA, I2=0.708 kA, and I3=1.48 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.200E-03 T-m
 * b) 4.620E-03 T-m
 * c) 5.082E-03 T-m
 * d) 5.590E-03 T-m
 * e) 6.149E-03 T-m

2) Three wires sit at the corners of a square of length 0.699 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.87 A, 2.18 A, 1.34 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.999E-05 T
 * b) By= 7.699E-05 T
 * c) By= 8.469E-05 T
 * d) By= 9.316E-05 T
 * e) By= 1.025E-04 T

3) Three wires sit at the corners of a square of length 0.533 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.17 A, 2.25 A, 2.22 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 1.037E-04 T
 * b) Bx= 1.141E-04 T
 * c) Bx= 1.255E-04 T
 * d) Bx= 1.381E-04 T
 * e) Bx= 1.519E-04 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.259 m and $$B_{max}=\,$$ 0.575 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.191 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.492E+05 A
 * b) 3.841E+05 A
 * c) 4.225E+05 A
 * d) 4.648E+05 A
 * e) 5.113E+05 A

c12 I0
1) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * a) 4.799E-02 T
 * b) 5.278E-02 T
 * c) 5.806E-02 T
 * d) 6.387E-02 T
 * e) 7.026E-02 T

2) Two parallel wires each carry a 7.68 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.36 cm, 1.58 cm), while the other is located at (5.29 cm, 5.18 cm). What is the force per unit length between the wires?


 * a) 1.973E-10 N/m
 * b) 2.170E-10 N/m
 * c) 2.387E-10 N/m
 * d) 2.625E-10 N/m
 * e) 2.888E-10 N/m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.32 kA, I2=2.0 kA, and I3=3.66 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.724E-03 T-m
 * b) 1.896E-03 T-m
 * c) 2.086E-03 T-m
 * d) 2.295E-03 T-m
 * e) 2.524E-03 T-m

4) Three wires sit at the corners of a square of length 0.687 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.38 A, 1.87 A, 2.03 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.134E-05 T
 * b) Bx= 7.847E-05 T
 * c) Bx= 8.632E-05 T
 * d) Bx= 9.495E-05 T
 * e) Bx= 1.044E-04 T

c12 I1
1) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * a) 2.634E-11 N/m
 * b) 2.897E-11 N/m
 * c) 3.187E-11 N/m
 * d) 3.506E-11 N/m
 * e) 3.856E-11 N/m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=2.33 kA, and I3=5.35 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.795E-03 T-m
 * b) 4.175E-03 T-m
 * c) 4.592E-03 T-m
 * d) 5.051E-03 T-m
 * e) 5.556E-03 T-m

3) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 8.371E-05 T
 * b) Bx= 9.208E-05 T
 * c) Bx= 1.013E-04 T
 * d) Bx= 1.114E-04 T
 * e) Bx= 1.226E-04 T

4) Two loops of wire carry the same current of 85 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.854 m while the other has a radius of 1.18 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.5 m from the first (smaller) loopif the disance between the loops is 1.66 m?


 * a) 4.253E-02 T
 * b) 4.678E-02 T
 * c) 5.146E-02 T
 * d) 5.661E-02 T
 * e) 6.227E-02 T

c12 I2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.547E-03 T-m
 * b) 1.702E-03 T-m
 * c) 1.872E-03 T-m
 * d) 2.060E-03 T-m
 * e) 2.266E-03 T-m

2) Two loops of wire carry the same current of 85 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.854 m while the other has a radius of 1.18 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.5 m from the first (smaller) loopif the disance between the loops is 1.66 m?


 * a) 4.253E-02 T
 * b) 4.678E-02 T
 * c) 5.146E-02 T
 * d) 5.661E-02 T
 * e) 6.227E-02 T

3) Two parallel wires each carry a 4.15 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.19 cm, 1.78 cm), while the other is located at (3.73 cm, 4.12 cm). What is the force per unit length between the wires?


 * a) 1.434E-10 N/m
 * b) 1.578E-10 N/m
 * c) 1.736E-10 N/m
 * d) 1.909E-10 N/m
 * e) 2.100E-10 N/m

4) Three wires sit at the corners of a square of length 0.688 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.73 A, 1.37 A, 1.65 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.171E-05 T
 * b) Bx= 6.788E-05 T
 * c) Bx= 7.467E-05 T
 * d) Bx= 8.213E-05 T
 * e) Bx= 9.035E-05 T

c12 J0
1) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * a) 6.099E-03 T
 * b) 6.709E-03 T
 * c) 7.380E-03 T
 * d) 8.118E-03 T
 * e) 8.930E-03 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=2.33 kA, and I3=5.35 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.795E-03 T-m
 * b) 4.175E-03 T-m
 * c) 4.592E-03 T-m
 * d) 5.051E-03 T-m
 * e) 5.556E-03 T-m

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.028E-05 T
 * b) By= 4.431E-05 T
 * c) By= 4.874E-05 T
 * d) By= 5.361E-05 T
 * e) By= 5.897E-05 T

4) Two parallel wires each carry a 7.48 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.13 cm, 0.955 cm), while the other is located at (5.37 cm, 5.48 cm). What is the force per unit length between the wires?


 * a) 2.015E-10 N/m
 * b) 2.216E-10 N/m
 * c) 2.438E-10 N/m
 * d) 2.682E-10 N/m
 * e) 2.950E-10 N/m

c12 J1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=1.32 kA, and I3=2.73 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.331E-03 T-m
 * b) 1.464E-03 T-m
 * c) 1.611E-03 T-m
 * d) 1.772E-03 T-m
 * e) 1.949E-03 T-m

2) Three wires sit at the corners of a square of length 0.76 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.91 A, 1.34 A, 1.05 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 5.611E-05 T
 * b) By= 6.172E-05 T
 * c) By= 6.789E-05 T
 * d) By= 7.468E-05 T
 * e) By= 8.215E-05 T

3) Two parallel wires each carry a 7.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.98 cm, 0.969 cm), while the other is located at (5.13 cm, 5.53 cm). What is the force per unit length between the wires?


 * a) 1.840E-10 N/m
 * b) 2.024E-10 N/m
 * c) 2.227E-10 N/m
 * d) 2.449E-10 N/m
 * e) 2.694E-10 N/m

4) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * a) 7.836E-03 T
 * b) 8.620E-03 T
 * c) 9.482E-03 T
 * d) 1.043E-02 T
 * e) 1.147E-02 T

c12 J2
1) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * a) 1.127E-02 T
 * b) 1.240E-02 T
 * c) 1.364E-02 T
 * d) 1.500E-02 T
 * e) 1.650E-02 T

2) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.576E-05 T
 * b) By= 8.333E-05 T
 * c) By= 9.167E-05 T
 * d) By= 1.008E-04 T
 * e) By= 1.109E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 8.204E-04 T-m
 * b) 9.025E-04 T-m
 * c) 9.927E-04 T-m
 * d) 1.092E-03 T-m
 * e) 1.201E-03 T-m

4) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * a) 2.449E-10 N/m
 * b) 2.694E-10 N/m
 * c) 2.963E-10 N/m
 * d) 3.260E-10 N/m
 * e) 3.586E-10 N/m

c12 K0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.57 kA, I2=0.708 kA, and I3=1.48 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.200E-03 T-m
 * b) 4.620E-03 T-m
 * c) 5.082E-03 T-m
 * d) 5.590E-03 T-m
 * e) 6.149E-03 T-m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=0.476 kA, and I3=1.57 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.250E-03 T-m
 * b) 1.375E-03 T-m
 * c) 1.512E-03 T-m
 * d) 1.663E-03 T-m
 * e) 1.830E-03 T-m

3) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * a) 7.952E-03 T
 * b) 8.747E-03 T
 * c) 9.622E-03 T
 * d) 1.058E-02 T
 * e) 1.164E-02 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.171E+05 A
 * b) 2.388E+05 A
 * c) 2.627E+05 A
 * d) 2.890E+05 A
 * e) 3.179E+05 A

c12 K1
1) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * a) 7.836E-03 T
 * b) 8.620E-03 T
 * c) 9.482E-03 T
 * d) 1.043E-02 T
 * e) 1.147E-02 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.547 m and $$B_{max}=\,$$ 0.597 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.158 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.751E+05 A
 * b) 1.927E+05 A
 * c) 2.119E+05 A
 * d) 2.331E+05 A
 * e) 2.564E+05 A

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.61 kA, I2=2.2 kA, and I3=5.1 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.644E-03 T-m
 * b) 4.009E-03 T-m
 * c) 4.410E-03 T-m
 * d) 4.850E-03 T-m
 * e) 5.336E-03 T-m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=1.58 kA, and I3=4.31 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.386E-03 T-m
 * b) 4.825E-03 T-m
 * c) 5.307E-03 T-m
 * d) 5.838E-03 T-m
 * e) 6.421E-03 T-m

c12 K2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 5.255E-03 T-m
 * b) 5.781E-03 T-m
 * c) 6.359E-03 T-m
 * d) 6.994E-03 T-m
 * e) 7.694E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.549 m and $$B_{max}=\,$$ 0.599 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.29 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 5.581E+05 A
 * b) 6.139E+05 A
 * c) 6.752E+05 A
 * d) 7.428E+05 A
 * e) 8.170E+05 A

3) Two loops of wire carry the same current of 44 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.678 m while the other has a radius of 1.14 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.508 m from the first (smaller) loopif the disance between the loops is 1.16 m?


 * a) 3.342E-02 T
 * b) 3.676E-02 T
 * c) 4.044E-02 T
 * d) 4.448E-02 T
 * e) 4.893E-02 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.48 kA, I2=1.47 kA, and I3=2.6 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.420E-03 T-m
 * b) 1.562E-03 T-m
 * c) 1.718E-03 T-m
 * d) 1.890E-03 T-m
 * e) 2.079E-03 T-m

c12 L0
1) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * a) 2.176E-04 T-m
 * b) 2.393E-04 T-m
 * c) 2.633E-04 T-m
 * d) 2.896E-04 T-m
 * e) 3.186E-04 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.208E-05 T
 * b) 1.329E-05 T
 * c) 1.462E-05 T
 * d) 1.608E-05 T
 * e) 1.769E-05 T

3) Three wires sit at the corners of a square of length 0.532 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.11 A, 1.25 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 5.930E-05 T
 * b) By= 6.523E-05 T
 * c) By= 7.175E-05 T
 * d) By= 7.892E-05 T
 * e) By= 8.682E-05 T

4) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * a) 4.412E-10 N/m
 * b) 4.853E-10 N/m
 * c) 5.338E-10 N/m
 * d) 5.872E-10 N/m
 * e) 6.459E-10 N/m

c12 L1
1) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * a) 2.977E-11 N/m
 * b) 3.274E-11 N/m
 * c) 3.602E-11 N/m
 * d) 3.962E-11 N/m
 * e) 4.358E-11 N/m

2) A solenoid has 7.690E+04 turns wound around a cylinder of diameter 1.63 cm and length 11 m. The current through the coils is 0.728 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.76 cm to z=+1.99 cm


 * a) 2.762E-04 T-m
 * b) 3.038E-04 T-m
 * c) 3.342E-04 T-m
 * d) 3.676E-04 T-m
 * e) 4.043E-04 T-m

3) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.576E-05 T
 * b) By= 8.333E-05 T
 * c) By= 9.167E-05 T
 * d) By= 1.008E-04 T
 * e) By= 1.109E-04 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.098E-05 T
 * b) 1.208E-05 T
 * c) 1.329E-05 T
 * d) 1.462E-05 T
 * e) 1.608E-05 T

c12 L2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.64 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.920E-05 T
 * b) 2.112E-05 T
 * c) 2.323E-05 T
 * d) 2.556E-05 T
 * e) 2.811E-05 T

2) Three wires sit at the corners of a square of length 0.547 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.78 A, 1.34 A, 1.64 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.118E-05 T
 * b) By= 6.730E-05 T
 * c) By= 7.403E-05 T
 * d) By= 8.144E-05 T
 * e) By= 8.958E-05 T

3) A solenoid has 5.500E+04 turns wound around a cylinder of diameter 1.45 cm and length 15 m. The current through the coils is 0.395 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.19 cm to z=+2.16 cm


 * a) 7.894E-05 T-m
 * b) 8.683E-05 T-m
 * c) 9.551E-05 T-m
 * d) 1.051E-04 T-m
 * e) 1.156E-04 T-m

4) Two parallel wires each carry a 2.12 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.67 cm, 1.25 cm), while the other is located at (4.69 cm, 4.27 cm). What is the force per unit length between the wires?


 * a) 2.119E-11 N/m
 * b) 2.331E-11 N/m
 * c) 2.564E-11 N/m
 * d) 2.820E-11 N/m
 * e) 3.102E-11 N/m

c12 M0
1) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.518E-05 T
 * b) By= 8.270E-05 T
 * c) By= 9.097E-05 T
 * d) By= 1.001E-04 T
 * e) By= 1.101E-04 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.35 kA, I2=0.809 kA, and I3=2.34 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.031E-03 T-m
 * b) 4.434E-03 T-m
 * c) 4.877E-03 T-m
 * d) 5.365E-03 T-m
 * e) 5.901E-03 T-m

3) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * a) 1.564E-02 T
 * b) 1.720E-02 T
 * c) 1.892E-02 T
 * d) 2.081E-02 T
 * e) 2.289E-02 T

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * a) 3.882E-10 N/m
 * b) 4.270E-10 N/m
 * c) 4.697E-10 N/m
 * d) 5.167E-10 N/m
 * e) 5.683E-10 N/m

c12 M1
1) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * a) 1.564E-02 T
 * b) 1.720E-02 T
 * c) 1.892E-02 T
 * d) 2.081E-02 T
 * e) 2.289E-02 T

2) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.035E-05 T
 * b) By= 7.739E-05 T
 * c) By= 8.512E-05 T
 * d) By= 9.364E-05 T
 * e) By= 1.030E-04 T

3) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * a) 2.977E-11 N/m
 * b) 3.274E-11 N/m
 * c) 3.602E-11 N/m
 * d) 3.962E-11 N/m
 * e) 4.358E-11 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.33 kA, I2=0.741 kA, and I3=2.21 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.261E-03 T-m
 * b) 3.587E-03 T-m
 * c) 3.945E-03 T-m
 * d) 4.340E-03 T-m
 * e) 4.774E-03 T-m

c12 M2
1) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * a) 7.836E-03 T
 * b) 8.620E-03 T
 * c) 9.482E-03 T
 * d) 1.043E-02 T
 * e) 1.147E-02 T

2) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.028E-05 T
 * b) By= 4.431E-05 T
 * c) By= 4.874E-05 T
 * d) By= 5.361E-05 T
 * e) By= 5.897E-05 T

3) Two parallel wires each carry a 7.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.62 cm, 1.31 cm), while the other is located at (4.63 cm, 5.53 cm). What is the force per unit length between the wires?


 * a) 2.588E-10 N/m
 * b) 2.847E-10 N/m
 * c) 3.131E-10 N/m
 * d) 3.444E-10 N/m
 * e) 3.789E-10 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.770E-03 T-m
 * b) 4.147E-03 T-m
 * c) 4.562E-03 T-m
 * d) 5.018E-03 T-m
 * e) 5.520E-03 T-m

c12 N0
1) Two loops of wire carry the same current of 11 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.424 m while the other has a radius of 1.32 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.52 m from the first (smaller) loopif the disance between the loops is 1.25 m?


 * a) 7.623E-03 T
 * b) 8.385E-03 T
 * c) 9.223E-03 T
 * d) 1.015E-02 T
 * e) 1.116E-02 T

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 1.791E-05 T
 * b) 1.970E-05 T
 * c) 2.167E-05 T
 * d) 2.384E-05 T
 * e) 2.622E-05 T

3) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T

4) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * a) 1.121E-04 T-m
 * b) 1.233E-04 T-m
 * c) 1.356E-04 T-m
 * d) 1.492E-04 T-m
 * e) 1.641E-04 T-m

c12 N1
1) A solenoid has 7.920E+04 turns wound around a cylinder of diameter 1.45 cm and length 11 m. The current through the coils is 0.702 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.27 cm to z=+1.36 cm


 * a) 2.687E-04 T-m
 * b) 2.955E-04 T-m
 * c) 3.251E-04 T-m
 * d) 3.576E-04 T-m
 * e) 3.934E-04 T-m

2) Three wires sit at the corners of a square of length 0.796 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.48 A, 1.4 A, 1.47 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 4.506E-05 T
 * b) Bx= 4.957E-05 T
 * c) Bx= 5.452E-05 T
 * d) Bx= 5.997E-05 T
 * e) Bx= 6.597E-05 T

3) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * a) 1.127E-02 T
 * b) 1.240E-02 T
 * c) 1.364E-02 T
 * d) 1.500E-02 T
 * e) 1.650E-02 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 3.33 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 2.202E-05 T
 * b) 2.422E-05 T
 * c) 2.664E-05 T
 * d) 2.930E-05 T
 * e) 3.223E-05 T

c12 N2
1) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * a) 2.176E-04 T-m
 * b) 2.393E-04 T-m
 * c) 2.633E-04 T-m
 * d) 2.896E-04 T-m
 * e) 3.186E-04 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.26 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.494E-05 T
 * b) 1.644E-05 T
 * c) 1.808E-05 T
 * d) 1.989E-05 T
 * e) 2.188E-05 T

3) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 8.371E-05 T
 * b) Bx= 9.208E-05 T
 * c) Bx= 1.013E-04 T
 * d) Bx= 1.114E-04 T
 * e) Bx= 1.226E-04 T

4) Two loops of wire carry the same current of 99 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.798 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.394 m from the first (smaller) loopif the disance between the loops is 1.29 m?


 * a) 8.291E-02 T
 * b) 9.120E-02 T
 * c) 1.003E-01 T
 * d) 1.104E-01 T
 * e) 1.214E-01 T

c12 O0
1) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 8.371E-05 T
 * b) Bx= 9.208E-05 T
 * c) Bx= 1.013E-04 T
 * d) Bx= 1.114E-04 T
 * e) Bx= 1.226E-04 T

2) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * a) 1.121E-04 T-m
 * b) 1.233E-04 T-m
 * c) 1.356E-04 T-m
 * d) 1.492E-04 T-m
 * e) 1.641E-04 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.49 kA, I2=0.996 kA, and I3=2.61 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.385E-03 T-m
 * b) 1.524E-03 T-m
 * c) 1.676E-03 T-m
 * d) 1.844E-03 T-m
 * e) 2.028E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.51 m and $$B_{max}=\,$$ 0.649 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.376 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 9.388E+05 A
 * b) 1.033E+06 A
 * c) 1.136E+06 A
 * d) 1.249E+06 A
 * e) 1.374E+06 A

c12 O1
1) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T

2) A solenoid has 9.160E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.873 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.74 cm to z=+4.75 cm


 * a) 3.369E-04 T-m
 * b) 3.706E-04 T-m
 * c) 4.076E-04 T-m
 * d) 4.484E-04 T-m
 * e) 4.932E-04 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 8.204E-04 T-m
 * b) 9.025E-04 T-m
 * c) 9.927E-04 T-m
 * d) 1.092E-03 T-m
 * e) 1.201E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

c12 O2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.171E+05 A
 * b) 2.388E+05 A
 * c) 2.627E+05 A
 * d) 2.890E+05 A
 * e) 3.179E+05 A

2) Three wires sit at the corners of a square of length 0.784 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.19 A, 1.51 A, 2.18 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.487E-05 T
 * b) Bx= 8.236E-05 T
 * c) Bx= 9.060E-05 T
 * d) Bx= 9.966E-05 T
 * e) Bx= 1.096E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.64 kA, and I3=4.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 2.721E-03 T-m
 * b) 2.993E-03 T-m
 * c) 3.292E-03 T-m
 * d) 3.621E-03 T-m
 * e) 3.984E-03 T-m

4) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * a) 1.863E-04 T-m
 * b) 2.050E-04 T-m
 * c) 2.255E-04 T-m
 * d) 2.480E-04 T-m
 * e) 2.728E-04 T-m

c12 P0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.547E-03 T-m
 * b) 1.702E-03 T-m
 * c) 1.872E-03 T-m
 * d) 2.060E-03 T-m
 * e) 2.266E-03 T-m

2) A wire carries a current of 303 A in a circular arc with radius 2.2 cm swept through 72 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.881E+00 Tesla
 * b) 4.269E+00 Tesla
 * c) 4.696E+00 Tesla
 * d) 5.165E+00 Tesla
 * e) 5.682E+00 Tesla

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.028E-05 T
 * b) By= 4.431E-05 T
 * c) By= 4.874E-05 T
 * d) By= 5.361E-05 T
 * e) By= 5.897E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 18 turns per centimeter and the current applied to the solenoid is 582 mA, the net magnetic field is measured to be 1.15 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 7.211E+02
 * b) $$\chi \text{ (chi) }=$$ 7.932E+02
 * c) $$\chi \text{ (chi) }=$$ 8.726E+02
 * d) $$\chi \text{ (chi) }=$$ 9.598E+02
 * e) $$\chi \text{ (chi) }=$$ 1.056E+03

c12 P1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=0.476 kA, and I3=1.57 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.250E-03 T-m
 * b) 1.375E-03 T-m
 * c) 1.512E-03 T-m
 * d) 1.663E-03 T-m
 * e) 1.830E-03 T-m

2) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.518E-05 T
 * b) By= 8.270E-05 T
 * c) By= 9.097E-05 T
 * d) By= 1.001E-04 T
 * e) By= 1.101E-04 T

3) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.034E+00 Tesla
 * b) 5.538E+00 Tesla
 * c) 6.091E+00 Tesla
 * d) 6.701E+00 Tesla
 * e) 7.371E+00 Tesla

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 359 mA, the net magnetic field is measured to be 1.32 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.124E+03
 * b) $$\chi \text{ (chi) }=$$ 1.237E+03
 * c) $$\chi \text{ (chi) }=$$ 1.360E+03
 * d) $$\chi \text{ (chi) }=$$ 1.497E+03
 * e) $$\chi \text{ (chi) }=$$ 1.646E+03

c12 P2
1) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.711E+00 Tesla
 * b) 6.283E+00 Tesla
 * c) 6.911E+00 Tesla
 * d) 7.602E+00 Tesla
 * e) 8.362E+00 Tesla

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.49 kA, I2=0.996 kA, and I3=2.61 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.385E-03 T-m
 * b) 1.524E-03 T-m
 * c) 1.676E-03 T-m
 * d) 1.844E-03 T-m
 * e) 2.028E-03 T-m

3) Three wires sit at the corners of a square of length 0.716 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.94 A, 2.04 A, 2.41 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.833E-05 T
 * b) By= 7.517E-05 T
 * c) By= 8.268E-05 T
 * d) By= 9.095E-05 T
 * e) By= 1.000E-04 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 359 mA, the net magnetic field is measured to be 1.32 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.124E+03
 * b) $$\chi \text{ (chi) }=$$ 1.237E+03
 * c) $$\chi \text{ (chi) }=$$ 1.360E+03
 * d) $$\chi \text{ (chi) }=$$ 1.497E+03
 * e) $$\chi \text{ (chi) }=$$ 1.646E+03

c12 Q0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 5.255E-03 T-m
 * b) 5.781E-03 T-m
 * c) 6.359E-03 T-m
 * d) 6.994E-03 T-m
 * e) 7.694E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 8.204E-04 T-m
 * b) 9.025E-04 T-m
 * c) 9.927E-04 T-m
 * d) 1.092E-03 T-m
 * e) 1.201E-03 T-m

4) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * a) 4.412E-10 N/m
 * b) 4.853E-10 N/m
 * c) 5.338E-10 N/m
 * d) 5.872E-10 N/m
 * e) 6.459E-10 N/m

c12 Q1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.547E-03 T-m
 * b) 1.702E-03 T-m
 * c) 1.872E-03 T-m
 * d) 2.060E-03 T-m
 * e) 2.266E-03 T-m

2) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * a) 1.422E-11 N/m
 * b) 1.564E-11 N/m
 * c) 1.720E-11 N/m
 * d) 1.892E-11 N/m
 * e) 2.081E-11 N/m

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.382E+05 A
 * b) 3.720E+05 A
 * c) 4.092E+05 A
 * d) 4.502E+05 A
 * e) 4.952E+05 A

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.770E-03 T-m
 * b) 4.147E-03 T-m
 * c) 4.562E-03 T-m
 * d) 5.018E-03 T-m
 * e) 5.520E-03 T-m

c12 Q2
1) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * a) 2.634E-11 N/m
 * b) 2.897E-11 N/m
 * c) 3.187E-11 N/m
 * d) 3.506E-11 N/m
 * e) 3.856E-11 N/m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.770E-03 T-m
 * b) 4.147E-03 T-m
 * c) 4.562E-03 T-m
 * d) 5.018E-03 T-m
 * e) 5.520E-03 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.45 kA, I2=2.68 kA, and I3=5.5 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.544E-03 T-m
 * b) 3.898E-03 T-m
 * c) 4.288E-03 T-m
 * d) 4.717E-03 T-m
 * e) 5.188E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 5.479E+05 A
 * b) 6.027E+05 A
 * c) 6.630E+05 A
 * d) 7.293E+05 A
 * e) 8.022E+05 A

c12 R0
1) Two parallel wires each carry a 3.38 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.46 cm, 1.76 cm), while the other is located at (5.13 cm, 5.5 cm). What is the force per unit length between the wires?


 * a) 3.810E-11 N/m
 * b) 4.191E-11 N/m
 * c) 4.610E-11 N/m
 * d) 5.071E-11 N/m
 * e) 5.578E-11 N/m

2) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * a) 6.099E-03 T
 * b) 6.709E-03 T
 * c) 7.380E-03 T
 * d) 8.118E-03 T
 * e) 8.930E-03 T

3) Three wires sit at the corners of a square of length 0.688 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.73 A, 1.37 A, 1.65 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.171E-05 T
 * b) Bx= 6.788E-05 T
 * c) Bx= 7.467E-05 T
 * d) Bx= 8.213E-05 T
 * e) Bx= 9.035E-05 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.248 m and $$B_{max}=\,$$ 0.459 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.152 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.228E+05 A
 * b) 2.451E+05 A
 * c) 2.696E+05 A
 * d) 2.966E+05 A
 * e) 3.262E+05 A

c12 R1
1) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * a) 2.449E-10 N/m
 * b) 2.694E-10 N/m
 * c) 2.963E-10 N/m
 * d) 3.260E-10 N/m
 * e) 3.586E-10 N/m

2) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 4.559E-05 T
 * b) Bx= 5.015E-05 T
 * c) Bx= 5.517E-05 T
 * d) Bx= 6.068E-05 T
 * e) Bx= 6.675E-05 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.253 m and $$B_{max}=\,$$ 0.489 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.112 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.289E+05 A
 * b) 1.418E+05 A
 * c) 1.560E+05 A
 * d) 1.716E+05 A
 * e) 1.888E+05 A

4) Two loops of wire carry the same current of 88 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.655 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.531 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * a) 4.162E-02 T
 * b) 4.578E-02 T
 * c) 5.036E-02 T
 * d) 5.540E-02 T
 * e) 6.094E-02 T

c12 R2
1) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * a) 5.926E-11 N/m
 * b) 6.518E-11 N/m
 * c) 7.170E-11 N/m
 * d) 7.887E-11 N/m
 * e) 8.676E-11 N/m

2) Two loops of wire carry the same current of 21 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.753 m while the other has a radius of 1.47 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.406 m from the first (smaller) loopif the disance between the loops is 1.38 m?


 * a) 1.559E-02 T
 * b) 1.715E-02 T
 * c) 1.886E-02 T
 * d) 2.075E-02 T
 * e) 2.283E-02 T

3) Three wires sit at the corners of a square of length 0.51 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.16 A, 2.46 A, 2.15 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 9.053E-05 T
 * b) Bx= 9.959E-05 T
 * c) Bx= 1.095E-04 T
 * d) Bx= 1.205E-04 T
 * e) Bx= 1.325E-04 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

c12 S0
1) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.498E+00 Tesla
 * b) 3.848E+00 Tesla
 * c) 4.233E+00 Tesla
 * d) 4.656E+00 Tesla
 * e) 5.122E+00 Tesla

2) Two loops of wire carry the same current of 97 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.595 m while the other has a radius of 1.1 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.63 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * a) 5.302E-02 T
 * b) 5.832E-02 T
 * c) 6.415E-02 T
 * d) 7.056E-02 T
 * e) 7.762E-02 T

3) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.718E-05 T
 * b) By= 7.390E-05 T
 * c) By= 8.129E-05 T
 * d) By= 8.942E-05 T
 * e) By= 9.836E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=3.3 kA, and I3=5.85 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 5.598E-03 T-m
 * b) 6.158E-03 T-m
 * c) 6.773E-03 T-m
 * d) 7.451E-03 T-m
 * e) 8.196E-03 T-m

c12 S1
1) Three wires sit at the corners of a square of length 0.591 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.47 A, 2.1 A, 2.24 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 1.191E-04 T
 * b) By= 1.310E-04 T
 * c) By= 1.441E-04 T
 * d) By= 1.585E-04 T
 * e) By= 1.744E-04 T

2) A wire carries a current of 338 A in a circular arc with radius 2.62 cm swept through 79 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 4.387E+00 Tesla
 * b) 4.826E+00 Tesla
 * c) 5.309E+00 Tesla
 * d) 5.839E+00 Tesla
 * e) 6.423E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.46 kA, I2=2.14 kA, and I3=4.44 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.943E-03 T-m
 * b) 5.438E-03 T-m
 * c) 5.982E-03 T-m
 * d) 6.580E-03 T-m
 * e) 7.238E-03 T-m

4) Two loops of wire carry the same current of 29 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.76 m while the other has a radius of 1.12 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.544 m from the first (smaller) loopif the disance between the loops is 1.56 m?


 * a) 1.950E-02 T
 * b) 2.145E-02 T
 * c) 2.360E-02 T
 * d) 2.596E-02 T
 * e) 2.855E-02 T

c12 S2
1) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.718E-05 T
 * b) By= 7.390E-05 T
 * c) By= 8.129E-05 T
 * d) By= 8.942E-05 T
 * e) By= 9.836E-05 T

2) A wire carries a current of 353 A in a circular arc with radius 2.44 cm swept through 86 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.891E+00 Tesla
 * b) 6.481E+00 Tesla
 * c) 7.129E+00 Tesla
 * d) 7.841E+00 Tesla
 * e) 8.626E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=3.3 kA, and I3=5.85 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 5.598E-03 T-m
 * b) 6.158E-03 T-m
 * c) 6.773E-03 T-m
 * d) 7.451E-03 T-m
 * e) 8.196E-03 T-m

4) Two loops of wire carry the same current of 64 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.838 m while the other has a radius of 1.17 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.528 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * a) 3.863E-02 T
 * b) 4.249E-02 T
 * c) 4.674E-02 T
 * d) 5.141E-02 T
 * e) 5.655E-02 T

c12 T0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.64 kA, and I3=4.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 2.721E-03 T-m
 * b) 2.993E-03 T-m
 * c) 3.292E-03 T-m
 * d) 3.621E-03 T-m
 * e) 3.984E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.171E+05 A
 * b) 2.388E+05 A
 * c) 2.627E+05 A
 * d) 2.890E+05 A
 * e) 3.179E+05 A

3) Two parallel wires each carry a 6.53 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.82 cm, 1.17 cm), while the other is located at (4.07 cm, 5.5 cm). What is the force per unit length between the wires?


 * a) 1.788E-10 N/m
 * b) 1.966E-10 N/m
 * c) 2.163E-10 N/m
 * d) 2.379E-10 N/m
 * e) 2.617E-10 N/m

4) A wire carries a current of 202 A in a circular arc with radius 2.17 cm swept through 51 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 2.473E+00 Tesla
 * b) 2.720E+00 Tesla
 * c) 2.992E+00 Tesla
 * d) 3.291E+00 Tesla
 * e) 3.620E+00 Tesla

c12 T1
1) A wire carries a current of 297 A in a circular arc with radius 2.31 cm swept through 75 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.774E+00 Tesla
 * b) 4.151E+00 Tesla
 * c) 4.566E+00 Tesla
 * d) 5.023E+00 Tesla
 * e) 5.525E+00 Tesla

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.08 kA, and I3=1.77 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 7.166E-04 T-m
 * b) 7.883E-04 T-m
 * c) 8.671E-04 T-m
 * d) 9.538E-04 T-m
 * e) 1.049E-03 T-m

3) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * a) 1.283E-10 N/m
 * b) 1.411E-10 N/m
 * c) 1.552E-10 N/m
 * d) 1.708E-10 N/m
 * e) 1.878E-10 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.547 m and $$B_{max}=\,$$ 0.597 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.158 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.751E+05 A
 * b) 1.927E+05 A
 * c) 2.119E+05 A
 * d) 2.331E+05 A
 * e) 2.564E+05 A

c12 T2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

2) A wire carries a current of 303 A in a circular arc with radius 2.2 cm swept through 72 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.881E+00 Tesla
 * b) 4.269E+00 Tesla
 * c) 4.696E+00 Tesla
 * d) 5.165E+00 Tesla
 * e) 5.682E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.81 kA, and I3=3.23 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.622E-03 T-m
 * b) 1.784E-03 T-m
 * c) 1.963E-03 T-m
 * d) 2.159E-03 T-m
 * e) 2.375E-03 T-m

4) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * a) 2.449E-10 N/m
 * b) 2.694E-10 N/m
 * c) 2.963E-10 N/m
 * d) 3.260E-10 N/m
 * e) 3.586E-10 N/m

c12 U0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.407 m and $$B_{max}=\,$$ 0.605 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.583E+05 A
 * b) 3.941E+05 A
 * c) 4.335E+05 A
 * d) 4.769E+05 A
 * e) 5.246E+05 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 20 turns per centimeter and the current applied to the solenoid is 344 mA, the net magnetic field is measured to be 1.24 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.185E+03
 * b) $$\chi \text{ (chi) }=$$ 1.303E+03
 * c) $$\chi \text{ (chi) }=$$ 1.433E+03
 * d) $$\chi \text{ (chi) }=$$ 1.577E+03
 * e) $$\chi \text{ (chi) }=$$ 1.734E+03

3) Two parallel wires each carry a 4.15 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.19 cm, 1.78 cm), while the other is located at (3.73 cm, 4.12 cm). What is the force per unit length between the wires?


 * a) 1.434E-10 N/m
 * b) 1.578E-10 N/m
 * c) 1.736E-10 N/m
 * d) 1.909E-10 N/m
 * e) 2.100E-10 N/m

4) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * a) 1.121E-04 T-m
 * b) 1.233E-04 T-m
 * c) 1.356E-04 T-m
 * d) 1.492E-04 T-m
 * e) 1.641E-04 T-m

c12 U1
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 533 mA, the net magnetic field is measured to be 1.31 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 7.512E+02
 * b) $$\chi \text{ (chi) }=$$ 8.264E+02
 * c) $$\chi \text{ (chi) }=$$ 9.090E+02
 * d) $$\chi \text{ (chi) }=$$ 9.999E+02
 * e) $$\chi \text{ (chi) }=$$ 1.100E+03

3) A solenoid has 7.690E+04 turns wound around a cylinder of diameter 1.63 cm and length 11 m. The current through the coils is 0.728 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.76 cm to z=+1.99 cm


 * a) 2.762E-04 T-m
 * b) 3.038E-04 T-m
 * c) 3.342E-04 T-m
 * d) 3.676E-04 T-m
 * e) 4.043E-04 T-m

4) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * a) 1.283E-10 N/m
 * b) 1.411E-10 N/m
 * c) 1.552E-10 N/m
 * d) 1.708E-10 N/m
 * e) 1.878E-10 N/m

c12 U2
1) A solenoid has 5.160E+04 turns wound around a cylinder of diameter 1.55 cm and length 18 m. The current through the coils is 0.57 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.88 cm to z=+1.52 cm


 * a) 6.788E-05 T-m
 * b) 7.467E-05 T-m
 * c) 8.213E-05 T-m
 * d) 9.035E-05 T-m
 * e) 9.938E-05 T-m

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 27 turns per centimeter and the current applied to the solenoid is 280 mA, the net magnetic field is measured to be 1.13 T. What is the magnetic susceptibility for this case?


 * a) $$\chi \text{ (chi) }=$$ 1.188E+03
 * b) $$\chi \text{ (chi) }=$$ 1.307E+03
 * c) $$\chi \text{ (chi) }=$$ 1.438E+03
 * d) $$\chi \text{ (chi) }=$$ 1.582E+03
 * e) $$\chi \text{ (chi) }=$$ 1.740E+03

3) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * a) 2.634E-11 N/m
 * b) 2.897E-11 N/m
 * c) 3.187E-11 N/m
 * d) 3.506E-11 N/m
 * e) 3.856E-11 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.852 m and $$B_{max}=\,$$ 0.476 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.212 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.502E+05 A
 * b) 1.652E+05 A
 * c) 1.817E+05 A
 * d) 1.999E+05 A
 * e) 2.199E+05 A

c12 V0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 5.479E+05 A
 * b) 6.027E+05 A
 * c) 6.630E+05 A
 * d) 7.293E+05 A
 * e) 8.022E+05 A

2) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * a) 6.099E-03 T
 * b) 6.709E-03 T
 * c) 7.380E-03 T
 * d) 8.118E-03 T
 * e) 8.930E-03 T

3) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * a) 1.121E-04 T-m
 * b) 1.233E-04 T-m
 * c) 1.356E-04 T-m
 * d) 1.492E-04 T-m
 * e) 1.641E-04 T-m

4) Three wires sit at the corners of a square of length 0.716 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.94 A, 2.04 A, 2.41 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.833E-05 T
 * b) By= 7.517E-05 T
 * c) By= 8.268E-05 T
 * d) By= 9.095E-05 T
 * e) By= 1.000E-04 T

c12 V1
1) A solenoid has 9.560E+04 turns wound around a cylinder of diameter 1.18 cm and length 12 m. The current through the coils is 0.664 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.49 cm to z=+3.61 cm


 * a) 4.895E-04 T-m
 * b) 5.384E-04 T-m
 * c) 5.923E-04 T-m
 * d) 6.515E-04 T-m
 * e) 7.167E-04 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 7.876E+05 A
 * b) 8.664E+05 A
 * c) 9.530E+05 A
 * d) 1.048E+06 A
 * e) 1.153E+06 A

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.028E-05 T
 * b) By= 4.431E-05 T
 * c) By= 4.874E-05 T
 * d) By= 5.361E-05 T
 * e) By= 5.897E-05 T

4) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * a) 1.564E-02 T
 * b) 1.720E-02 T
 * c) 1.892E-02 T
 * d) 2.081E-02 T
 * e) 2.289E-02 T

c12 V2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 5.479E+05 A
 * b) 6.027E+05 A
 * c) 6.630E+05 A
 * d) 7.293E+05 A
 * e) 8.022E+05 A

2) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 3.480E-05 T
 * b) By= 3.828E-05 T
 * c) By= 4.210E-05 T
 * d) By= 4.631E-05 T
 * e) By= 5.095E-05 T

3) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * a) 1.863E-04 T-m
 * b) 2.050E-04 T-m
 * c) 2.255E-04 T-m
 * d) 2.480E-04 T-m
 * e) 2.728E-04 T-m

4) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * a) 7.836E-03 T
 * b) 8.620E-03 T
 * c) 9.482E-03 T
 * d) 1.043E-02 T
 * e) 1.147E-02 T

c12 W0
1) Two loops of wire carry the same current of 64 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.838 m while the other has a radius of 1.17 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.528 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * a) 3.863E-02 T
 * b) 4.249E-02 T
 * c) 4.674E-02 T
 * d) 5.141E-02 T
 * e) 5.655E-02 T

2) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * a) 4.412E-10 N/m
 * b) 4.853E-10 N/m
 * c) 5.338E-10 N/m
 * d) 5.872E-10 N/m
 * e) 6.459E-10 N/m

3) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.718E-05 T
 * b) By= 7.390E-05 T
 * c) By= 8.129E-05 T
 * d) By= 8.942E-05 T
 * e) By= 9.836E-05 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 5.479E+05 A
 * b) 6.027E+05 A
 * c) 6.630E+05 A
 * d) 7.293E+05 A
 * e) 8.022E+05 A

c12 W1
1) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.035E-05 T
 * b) By= 7.739E-05 T
 * c) By= 8.512E-05 T
 * d) By= 9.364E-05 T
 * e) By= 1.030E-04 T

2) Two loops of wire carry the same current of 29 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.76 m while the other has a radius of 1.12 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.544 m from the first (smaller) loopif the disance between the loops is 1.56 m?


 * a) 1.950E-02 T
 * b) 2.145E-02 T
 * c) 2.360E-02 T
 * d) 2.596E-02 T
 * e) 2.855E-02 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.171E+05 A
 * b) 2.388E+05 A
 * c) 2.627E+05 A
 * d) 2.890E+05 A
 * e) 3.179E+05 A

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * a) 3.882E-10 N/m
 * b) 4.270E-10 N/m
 * c) 4.697E-10 N/m
 * d) 5.167E-10 N/m
 * e) 5.683E-10 N/m

c12 W2
1) Three wires sit at the corners of a square of length 0.534 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.45 A, 2.44 A, 1.61 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 9.388E-05 T
 * b) By= 1.033E-04 T
 * c) By= 1.136E-04 T
 * d) By= 1.250E-04 T
 * e) By= 1.375E-04 T

2) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * a) 4.799E-02 T
 * b) 5.278E-02 T
 * c) 5.806E-02 T
 * d) 6.387E-02 T
 * e) 7.026E-02 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 2.534E+05 A
 * b) 2.787E+05 A
 * c) 3.066E+05 A
 * d) 3.373E+05 A
 * e) 3.710E+05 A

4) Two parallel wires each carry a 7.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.62 cm, 1.31 cm), while the other is located at (4.63 cm, 5.53 cm). What is the force per unit length between the wires?


 * a) 2.588E-10 N/m
 * b) 2.847E-10 N/m
 * c) 3.131E-10 N/m
 * d) 3.444E-10 N/m
 * e) 3.789E-10 N/m

c12 X0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.32 kA, I2=2.0 kA, and I3=3.66 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.724E-03 T-m
 * b) 1.896E-03 T-m
 * c) 2.086E-03 T-m
 * d) 2.295E-03 T-m
 * e) 2.524E-03 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 3.324E-05 T
 * b) 3.657E-05 T
 * c) 4.022E-05 T
 * d) 4.424E-05 T
 * e) 4.867E-05 T

3) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * a) 4.412E-10 N/m
 * b) 4.853E-10 N/m
 * c) 5.338E-10 N/m
 * d) 5.872E-10 N/m
 * e) 6.459E-10 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.852 m and $$B_{max}=\,$$ 0.476 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.212 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 1.502E+05 A
 * b) 1.652E+05 A
 * c) 1.817E+05 A
 * d) 1.999E+05 A
 * e) 2.199E+05 A

c12 X1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.4 kA, I2=2.64 kA, and I3=3.96 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.133E-03 T-m
 * b) 1.246E-03 T-m
 * c) 1.371E-03 T-m
 * d) 1.508E-03 T-m
 * e) 1.659E-03 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * a) 3.324E-05 T
 * b) 3.657E-05 T
 * c) 4.022E-05 T
 * d) 4.424E-05 T
 * e) 4.867E-05 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 3.382E+05 A
 * b) 3.720E+05 A
 * c) 4.092E+05 A
 * d) 4.502E+05 A
 * e) 4.952E+05 A

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * a) 3.882E-10 N/m
 * b) 4.270E-10 N/m
 * c) 4.697E-10 N/m
 * d) 5.167E-10 N/m
 * e) 5.683E-10 N/m

c12 X2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 5 mm if the current is 1A?


 * a) 1.488E-05 T
 * b) 1.637E-05 T
 * c) 1.800E-05 T
 * d) 1.981E-05 T
 * e) 2.179E-05 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * a) 7.876E+05 A
 * b) 8.664E+05 A
 * c) 9.530E+05 A
 * d) 1.048E+06 A
 * e) 1.153E+06 A

3) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * a) 1.283E-10 N/m
 * b) 1.411E-10 N/m
 * c) 1.552E-10 N/m
 * d) 1.708E-10 N/m
 * e) 1.878E-10 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.44 kA, I2=1.1 kA, and I3=1.99 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.017E-03 T-m
 * b) 1.118E-03 T-m
 * c) 1.230E-03 T-m
 * d) 1.353E-03 T-m
 * e) 1.489E-03 T-m

c12 Y0
1) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 7.035E-05 T
 * b) By= 7.739E-05 T
 * c) By= 8.512E-05 T
 * d) By= 9.364E-05 T
 * e) By= 1.030E-04 T

2) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * a) 5.926E-11 N/m
 * b) 6.518E-11 N/m
 * c) 7.170E-11 N/m
 * d) 7.887E-11 N/m
 * e) 8.676E-11 N/m

3) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * a) 6.807E-05 T-m
 * b) 7.487E-05 T-m
 * c) 8.236E-05 T-m
 * d) 9.060E-05 T-m
 * e) 9.966E-05 T-m

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 6.545E-05 T
 * b) Bx= 7.200E-05 T
 * c) Bx= 7.919E-05 T
 * d) Bx= 8.711E-05 T
 * e) Bx= 9.583E-05 T

c12 Y1
1) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * a) 1.283E-10 N/m
 * b) 1.411E-10 N/m
 * c) 1.552E-10 N/m
 * d) 1.708E-10 N/m
 * e) 1.878E-10 N/m

2) Three wires sit at the corners of a square of length 0.819 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.01 A, 1.09 A, 1.56 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 4.688E-05 T
 * b) By= 5.156E-05 T
 * c) By= 5.672E-05 T
 * d) By= 6.239E-05 T
 * e) By= 6.863E-05 T

3) Three wires sit at the corners of a square of length 0.686 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.28 A, 1.27 A, 1.61 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 5.409E-05 T
 * b) Bx= 5.950E-05 T
 * c) Bx= 6.545E-05 T
 * d) Bx= 7.200E-05 T
 * e) Bx= 7.920E-05 T

4) A solenoid has 4.900E+04 turns wound around a cylinder of diameter 1.74 cm and length 19 m. The current through the coils is 0.432 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.18 cm to z=+1.77 cm


 * a) 6.884E-05 T-m
 * b) 7.573E-05 T-m
 * c) 8.330E-05 T-m
 * d) 9.163E-05 T-m
 * e) 1.008E-04 T-m

c12 Y2
1) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * a) 1.422E-11 N/m
 * b) 1.564E-11 N/m
 * c) 1.720E-11 N/m
 * d) 1.892E-11 N/m
 * e) 2.081E-11 N/m

2) A solenoid has 5.160E+04 turns wound around a cylinder of diameter 1.55 cm and length 18 m. The current through the coils is 0.57 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.88 cm to z=+1.52 cm


 * a) 6.788E-05 T-m
 * b) 7.467E-05 T-m
 * c) 8.213E-05 T-m
 * d) 9.035E-05 T-m
 * e) 9.938E-05 T-m

3) Three wires sit at the corners of a square of length 0.547 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.78 A, 1.34 A, 1.64 A), respectively. What is the y-component of the magnetic field at point P?


 * a) By= 6.118E-05 T
 * b) By= 6.730E-05 T
 * c) By= 7.403E-05 T
 * d) By= 8.144E-05 T
 * e) By= 8.958E-05 T

4) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T

c12 Z0
1) A wire carries a current of 109 A in a circular arc with radius 1.26 cm swept through 71 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 2.908E+00 Tesla
 * b) 3.199E+00 Tesla
 * c) 3.519E+00 Tesla
 * d) 3.871E+00 Tesla
 * e) 4.258E+00 Tesla

2) Three wires sit at the corners of a square of length 0.784 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.19 A, 1.51 A, 2.18 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.487E-05 T
 * b) Bx= 8.236E-05 T
 * c) Bx= 9.060E-05 T
 * d) Bx= 9.966E-05 T
 * e) Bx= 1.096E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.5 kA, I2=1.53 kA, and I3=2.34 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.018E-03 T-m
 * b) 1.120E-03 T-m
 * c) 1.232E-03 T-m
 * d) 1.355E-03 T-m
 * e) 1.490E-03 T-m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.16 kA, and I3=2.13 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 2.815E-03 T-m
 * b) 3.097E-03 T-m
 * c) 3.406E-03 T-m
 * d) 3.747E-03 T-m
 * e) 4.122E-03 T-m

c12 Z1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.16 kA, and I3=2.13 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 2.815E-03 T-m
 * b) 3.097E-03 T-m
 * c) 3.406E-03 T-m
 * d) 3.747E-03 T-m
 * e) 4.122E-03 T-m

2) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 5.711E+00 Tesla
 * b) 6.283E+00 Tesla
 * c) 6.911E+00 Tesla
 * d) 7.602E+00 Tesla
 * e) 8.362E+00 Tesla

3) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 4.559E-05 T
 * b) Bx= 5.015E-05 T
 * c) Bx= 5.517E-05 T
 * d) Bx= 6.068E-05 T
 * e) Bx= 6.675E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.48 kA, I2=1.47 kA, and I3=2.6 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 1.420E-03 T-m
 * b) 1.562E-03 T-m
 * c) 1.718E-03 T-m
 * d) 1.890E-03 T-m
 * e) 2.079E-03 T-m

c12 Z2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.5 kA, I2=1.28 kA, and I3=3.4 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 4.362E-03 T-m
 * b) 4.798E-03 T-m
 * c) 5.278E-03 T-m
 * d) 5.806E-03 T-m
 * e) 6.386E-03 T-m

2) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * a) 3.498E+00 Tesla
 * b) 3.848E+00 Tesla
 * c) 4.233E+00 Tesla
 * d) 4.656E+00 Tesla
 * e) 5.122E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.61 kA, I2=2.2 kA, and I3=5.1 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * a) 3.644E-03 T-m
 * b) 4.009E-03 T-m
 * c) 4.410E-03 T-m
 * d) 4.850E-03 T-m
 * e) 5.336E-03 T-m

4) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * a) Bx= 7.270E-05 T
 * b) Bx= 7.997E-05 T
 * c) Bx= 8.797E-05 T
 * d) Bx= 9.677E-05 T
 * e) Bx= 1.064E-04 T


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Key: A0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.277E+05 A
 * -b) 3.604E+05 A
 * -c) 3.965E+05 A
 * -d) 4.361E+05 A
 * +e) 4.797E+05 A

2) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * -a) 7.952E-03 T
 * -b) 8.747E-03 T
 * -c) 9.622E-03 T
 * -d) 1.058E-02 T
 * +e) 1.164E-02 T

3) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * -a) 5.926E-11 N/m
 * +b) 6.518E-11 N/m
 * -c) 7.170E-11 N/m
 * -d) 7.887E-11 N/m
 * -e) 8.676E-11 N/m

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 1.791E-05 T
 * -b) 1.970E-05 T
 * -c) 2.167E-05 T
 * -d) 2.384E-05 T
 * +e) 2.622E-05 T

Click these links for the keys:

Key: A1
1) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * -a) 1.422E-11 N/m
 * -b) 1.564E-11 N/m
 * -c) 1.720E-11 N/m
 * +d) 1.892E-11 N/m
 * -e) 2.081E-11 N/m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 1.791E-05 T
 * -b) 1.970E-05 T
 * -c) 2.167E-05 T
 * -d) 2.384E-05 T
 * +e) 2.622E-05 T

3) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * -a) 4.799E-02 T
 * -b) 5.278E-02 T
 * +c) 5.806E-02 T
 * -d) 6.387E-02 T
 * -e) 7.026E-02 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.871 m and $$B_{max}=\,$$ 0.427 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.688 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 1.404E+06 A
 * -b) 1.544E+06 A
 * -c) 1.699E+06 A
 * -d) 1.869E+06 A
 * -e) 2.056E+06 A

Click these links for the keys:

Key: A2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 1.208E-05 T
 * -b) 1.329E-05 T
 * -c) 1.462E-05 T
 * -d) 1.608E-05 T
 * -e) 1.769E-05 T

2) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * -a) 2.977E-11 N/m
 * -b) 3.274E-11 N/m
 * -c) 3.602E-11 N/m
 * -d) 3.962E-11 N/m
 * +e) 4.358E-11 N/m

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.645 m and $$B_{max}=\,$$ 0.469 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.26 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.949E+05 A
 * -b) 3.244E+05 A
 * -c) 3.568E+05 A
 * +d) 3.925E+05 A
 * -e) 4.317E+05 A

4) Two loops of wire carry the same current of 88 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.655 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.531 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * -a) 4.162E-02 T
 * -b) 4.578E-02 T
 * -c) 5.036E-02 T
 * +d) 5.540E-02 T
 * -e) 6.094E-02 T

Click these links for the keys:

Key: B0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.571 m and $$B_{max}=\,$$ 0.331 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.321 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.226E+05 A
 * -b) 3.549E+05 A
 * -c) 3.904E+05 A
 * +d) 4.294E+05 A
 * -e) 4.724E+05 A

2) Two parallel wires each carry a 2.12 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.67 cm, 1.25 cm), while the other is located at (4.69 cm, 4.27 cm). What is the force per unit length between the wires?


 * -a) 2.119E-11 N/m
 * -b) 2.331E-11 N/m
 * -c) 2.564E-11 N/m
 * +d) 2.820E-11 N/m
 * -e) 3.102E-11 N/m

3) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.545E-05 T
 * +b) Bx= 7.200E-05 T
 * -c) Bx= 7.919E-05 T
 * -d) Bx= 8.711E-05 T
 * -e) Bx= 9.583E-05 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 3.416E-05 T
 * -b) 3.758E-05 T
 * +c) 4.133E-05 T
 * -d) 4.547E-05 T
 * -e) 5.001E-05 T

Click these links for the keys:

Key: B1
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.66 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 1.935E-05 T
 * +b) 2.128E-05 T
 * -c) 2.341E-05 T
 * -d) 2.575E-05 T
 * -e) 2.832E-05 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 7.876E+05 A
 * -b) 8.664E+05 A
 * -c) 9.530E+05 A
 * -d) 1.048E+06 A
 * -e) 1.153E+06 A

3) Two parallel wires each carry a 7.48 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.13 cm, 0.955 cm), while the other is located at (5.37 cm, 5.48 cm). What is the force per unit length between the wires?


 * -a) 2.015E-10 N/m
 * +b) 2.216E-10 N/m
 * -c) 2.438E-10 N/m
 * -d) 2.682E-10 N/m
 * -e) 2.950E-10 N/m

4) Three wires sit at the corners of a square of length 0.51 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.16 A, 2.46 A, 2.15 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 9.053E-05 T
 * -b) Bx= 9.959E-05 T
 * -c) Bx= 1.095E-04 T
 * -d) Bx= 1.205E-04 T
 * +e) Bx= 1.325E-04 T

Click these links for the keys:

Key: B2
1) Three wires sit at the corners of a square of length 0.466 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.4 A, 2.42 A, 1.9 A), respectively. What is the x-component of the magnetic field at point P?


 * +a) Bx= 1.335E-04 T
 * -b) Bx= 1.468E-04 T
 * -c) Bx= 1.615E-04 T
 * -d) Bx= 1.777E-04 T
 * -e) Bx= 1.954E-04 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.382E+05 A
 * +b) 3.720E+05 A
 * -c) 4.092E+05 A
 * -d) 4.502E+05 A
 * -e) 4.952E+05 A

3) Two parallel wires each carry a 3.51 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.14 cm, 1.43 cm), while the other is located at (4.14 cm, 5.23 cm). What is the force per unit length between the wires?


 * +a) 6.484E-11 N/m
 * -b) 7.133E-11 N/m
 * -c) 7.846E-11 N/m
 * -d) 8.631E-11 N/m
 * -e) 9.494E-11 N/m

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.66 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 1.935E-05 T
 * +b) 2.128E-05 T
 * -c) 2.341E-05 T
 * -d) 2.575E-05 T
 * -e) 2.832E-05 T

Click these links for the keys:

Key: C0
1) Three wires sit at the corners of a square of length 0.76 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.91 A, 1.34 A, 1.05 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 5.611E-05 T
 * -b) By= 6.172E-05 T
 * +c) By= 6.789E-05 T
 * -d) By= 7.468E-05 T
 * -e) By= 8.215E-05 T

2) Three wires sit at the corners of a square of length 0.466 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.4 A, 2.42 A, 1.9 A), respectively. What is the x-component of the magnetic field at point P?


 * +a) Bx= 1.335E-04 T
 * -b) Bx= 1.468E-04 T
 * -c) Bx= 1.615E-04 T
 * -d) Bx= 1.777E-04 T
 * -e) Bx= 1.954E-04 T

3) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 5.034E+00 Tesla
 * -b) 5.538E+00 Tesla
 * -c) 6.091E+00 Tesla
 * -d) 6.701E+00 Tesla
 * -e) 7.371E+00 Tesla

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.59 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 2.072E-05 T
 * -b) 2.279E-05 T
 * -c) 2.507E-05 T
 * -d) 2.758E-05 T
 * -e) 3.034E-05 T

Click these links for the keys:

Key: C1
1) A wire carries a current of 269 A in a circular arc with radius 2.35 cm swept through 36 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 1.613E+00 Tesla
 * -b) 1.774E+00 Tesla
 * -c) 1.951E+00 Tesla
 * -d) 2.146E+00 Tesla
 * +e) 2.361E+00 Tesla

2) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 7.518E-05 T
 * -b) By= 8.270E-05 T
 * -c) By= 9.097E-05 T
 * -d) By= 1.001E-04 T
 * -e) By= 1.101E-04 T

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 3.324E-05 T
 * -b) 3.657E-05 T
 * +c) 4.022E-05 T
 * -d) 4.424E-05 T
 * -e) 4.867E-05 T

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.545E-05 T
 * +b) Bx= 7.200E-05 T
 * -c) Bx= 7.919E-05 T
 * -d) Bx= 8.711E-05 T
 * -e) Bx= 9.583E-05 T

Click these links for the keys:

Key: C2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 1.791E-05 T
 * -b) 1.970E-05 T
 * -c) 2.167E-05 T
 * -d) 2.384E-05 T
 * +e) 2.622E-05 T

2) Three wires sit at the corners of a square of length 0.64 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.76 A, 1.02 A, 1.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 3.394E-05 T
 * -b) Bx= 3.733E-05 T
 * -c) Bx= 4.106E-05 T
 * -d) Bx= 4.517E-05 T
 * +e) Bx= 4.969E-05 T

3) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.576E-05 T
 * +b) By= 8.333E-05 T
 * -c) By= 9.167E-05 T
 * -d) By= 1.008E-04 T
 * -e) By= 1.109E-04 T

4) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 3.498E+00 Tesla
 * -b) 3.848E+00 Tesla
 * -c) 4.233E+00 Tesla
 * -d) 4.656E+00 Tesla
 * -e) 5.122E+00 Tesla

Click these links for the keys:

Key: D0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.81 kA, I2=1.2 kA, and I3=1.84 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.583E-03 T-m
 * -b) 3.941E-03 T-m
 * +c) 4.335E-03 T-m
 * -d) 4.769E-03 T-m
 * -e) 5.246E-03 T-m

2) Two loops of wire carry the same current of 21 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.753 m while the other has a radius of 1.47 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.406 m from the first (smaller) loopif the disance between the loops is 1.38 m?


 * -a) 1.559E-02 T
 * +b) 1.715E-02 T
 * -c) 1.886E-02 T
 * -d) 2.075E-02 T
 * -e) 2.283E-02 T

3) A wire carries a current of 106 A in a circular arc with radius 1.32 cm swept through 38 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 1.589E+00 Tesla
 * +b) 1.748E+00 Tesla
 * -c) 1.923E+00 Tesla
 * -d) 2.116E+00 Tesla
 * -e) 2.327E+00 Tesla

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.277E+05 A
 * -b) 3.604E+05 A
 * -c) 3.965E+05 A
 * -d) 4.361E+05 A
 * +e) 4.797E+05 A

Click these links for the keys:

Key: D1
1) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 5.711E+00 Tesla
 * -b) 6.283E+00 Tesla
 * -c) 6.911E+00 Tesla
 * -d) 7.602E+00 Tesla
 * +e) 8.362E+00 Tesla

2) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * -a) 1.127E-02 T
 * -b) 1.240E-02 T
 * -c) 1.364E-02 T
 * +d) 1.500E-02 T
 * -e) 1.650E-02 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.78 kA, I2=2.61 kA, and I3=3.76 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 4.939E-03 T-m
 * -b) 5.432E-03 T-m
 * -c) 5.976E-03 T-m
 * -d) 6.573E-03 T-m
 * -e) 7.231E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.248 m and $$B_{max}=\,$$ 0.459 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.152 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.228E+05 A
 * -b) 2.451E+05 A
 * -c) 2.696E+05 A
 * +d) 2.966E+05 A
 * -e) 3.262E+05 A

Click these links for the keys:

Key: D2
1) Two loops of wire carry the same current of 24 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.53 m while the other has a radius of 1.38 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.485 m from the first (smaller) loopif the disance between the loops is 1.78 m?


 * -a) 1.294E-02 T
 * -b) 1.424E-02 T
 * +c) 1.566E-02 T
 * -d) 1.723E-02 T
 * -e) 1.895E-02 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 5.255E-03 T-m
 * -b) 5.781E-03 T-m
 * +c) 6.359E-03 T-m
 * -d) 6.994E-03 T-m
 * -e) 7.694E-03 T-m

3) A wire carries a current of 297 A in a circular arc with radius 2.31 cm swept through 75 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 3.774E+00 Tesla
 * -b) 4.151E+00 Tesla
 * -c) 4.566E+00 Tesla
 * -d) 5.023E+00 Tesla
 * +e) 5.525E+00 Tesla

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.407 m and $$B_{max}=\,$$ 0.605 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.583E+05 A
 * -b) 3.941E+05 A
 * +c) 4.335E+05 A
 * -d) 4.769E+05 A
 * -e) 5.246E+05 A

Click these links for the keys:

Key: E0
1) Three wires sit at the corners of a square of length 0.819 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.01 A, 1.09 A, 1.56 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 4.688E-05 T
 * -b) By= 5.156E-05 T
 * -c) By= 5.672E-05 T
 * +d) By= 6.239E-05 T
 * -e) By= 6.863E-05 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.770E-03 T-m
 * +b) 4.147E-03 T-m
 * -c) 4.562E-03 T-m
 * -d) 5.018E-03 T-m
 * -e) 5.520E-03 T-m

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.03 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 1.720E-05 T
 * -b) 1.892E-05 T
 * -c) 2.081E-05 T
 * +d) 2.289E-05 T
 * -e) 2.518E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 16 turns per centimeter and the current applied to the solenoid is 536 mA, the net magnetic field is measured to be 1.47 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 9.310E+02
 * -b) $$\chi \text{ (chi) }=$$ 1.024E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.126E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.239E+03
 * +e) $$\chi \text{ (chi) }=$$ 1.363E+03

Click these links for the keys:

Key: E1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=1.58 kA, and I3=4.31 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.386E-03 T-m
 * -b) 4.825E-03 T-m
 * -c) 5.307E-03 T-m
 * -d) 5.838E-03 T-m
 * +e) 6.421E-03 T-m

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 17 turns per centimeter and the current applied to the solenoid is 455 mA, the net magnetic field is measured to be 1.14 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 8.804E+02
 * -b) $$\chi \text{ (chi) }=$$ 9.685E+02
 * -c) $$\chi \text{ (chi) }=$$ 1.065E+03
 * +d) $$\chi \text{ (chi) }=$$ 1.172E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.289E+03

3) Three wires sit at the corners of a square of length 0.495 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.45 A, 1.66 A, 1.63 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 1.205E-04 T
 * +b) By= 1.325E-04 T
 * -c) By= 1.458E-04 T
 * -d) By= 1.604E-04 T
 * -e) By= 1.764E-04 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 1.488E-05 T
 * -b) 1.637E-05 T
 * -c) 1.800E-05 T
 * -d) 1.981E-05 T
 * -e) 2.179E-05 T

Click these links for the keys:

Key: E2
1) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 4.028E-05 T
 * -b) By= 4.431E-05 T
 * -c) By= 4.874E-05 T
 * -d) By= 5.361E-05 T
 * -e) By= 5.897E-05 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.354E-03 T-m
 * +b) 4.789E-03 T-m
 * -c) 5.268E-03 T-m
 * -d) 5.795E-03 T-m
 * -e) 6.374E-03 T-m

3) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.43 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 1.944E-05 T
 * -b) 2.138E-05 T
 * -c) 2.352E-05 T
 * -d) 2.587E-05 T
 * -e) 2.846E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 24 turns per centimeter and the current applied to the solenoid is 242 mA, the net magnetic field is measured to be 1.38 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 1.718E+03
 * +b) $$\chi \text{ (chi) }=$$ 1.890E+03
 * -c) $$\chi \text{ (chi) }=$$ 2.079E+03
 * -d) $$\chi \text{ (chi) }=$$ 2.287E+03
 * -e) $$\chi \text{ (chi) }=$$ 2.515E+03

Click these links for the keys:

Key: F0
1) A solenoid has 4.380E+04 turns wound around a cylinder of diameter 1.77 cm and length 16 m. The current through the coils is 0.916 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.39 cm to z=+4.26 cm


 * -a) 2.478E-04 T-m
 * +b) 2.726E-04 T-m
 * -c) 2.998E-04 T-m
 * -d) 3.298E-04 T-m
 * -e) 3.628E-04 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.259 m and $$B_{max}=\,$$ 0.575 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.191 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.492E+05 A
 * -b) 3.841E+05 A
 * -c) 4.225E+05 A
 * -d) 4.648E+05 A
 * +e) 5.113E+05 A

3) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 16 turns per centimeter and the current applied to the solenoid is 536 mA, the net magnetic field is measured to be 1.47 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 9.310E+02
 * -b) $$\chi \text{ (chi) }=$$ 1.024E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.126E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.239E+03
 * +e) $$\chi \text{ (chi) }=$$ 1.363E+03

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.545E-05 T
 * +b) Bx= 7.200E-05 T
 * -c) Bx= 7.919E-05 T
 * -d) Bx= 8.711E-05 T
 * -e) Bx= 9.583E-05 T

Click these links for the keys:

Key: F1
1) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 22 turns per centimeter and the current applied to the solenoid is 568 mA, the net magnetic field is measured to be 1.29 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 8.205E+02
 * -b) $$\chi \text{ (chi) }=$$ 9.026E+02
 * -c) $$\chi \text{ (chi) }=$$ 9.928E+02
 * -d) $$\chi \text{ (chi) }=$$ 1.092E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.201E+03

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.253 m and $$B_{max}=\,$$ 0.489 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.112 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.289E+05 A
 * -b) 1.418E+05 A
 * -c) 1.560E+05 A
 * -d) 1.716E+05 A
 * +e) 1.888E+05 A

3) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

4) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * -a) 6.807E-05 T-m
 * -b) 7.487E-05 T-m
 * +c) 8.236E-05 T-m
 * -d) 9.060E-05 T-m
 * -e) 9.966E-05 T-m

Click these links for the keys:

Key: F2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.51 m and $$B_{max}=\,$$ 0.649 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.376 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 9.388E+05 A
 * -b) 1.033E+06 A
 * +c) 1.136E+06 A
 * -d) 1.249E+06 A
 * -e) 1.374E+06 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 27 turns per centimeter and the current applied to the solenoid is 280 mA, the net magnetic field is measured to be 1.13 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 1.188E+03
 * -b) $$\chi \text{ (chi) }=$$ 1.307E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.438E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.582E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.740E+03

3) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.545E-05 T
 * +b) Bx= 7.200E-05 T
 * -c) Bx= 7.919E-05 T
 * -d) Bx= 8.711E-05 T
 * -e) Bx= 9.583E-05 T

4) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * -a) 1.863E-04 T-m
 * +b) 2.050E-04 T-m
 * -c) 2.255E-04 T-m
 * -d) 2.480E-04 T-m
 * -e) 2.728E-04 T-m

Click these links for the keys:

Key: G0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.354E-03 T-m
 * +b) 4.789E-03 T-m
 * -c) 5.268E-03 T-m
 * -d) 5.795E-03 T-m
 * -e) 6.374E-03 T-m

2) Two loops of wire carry the same current of 66 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.485 m while the other has a radius of 1.27 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.507 m from the first (smaller) loopif the disance between the loops is 1.76 m?


 * -a) 2.733E-02 T
 * -b) 3.007E-02 T
 * -c) 3.307E-02 T
 * -d) 3.638E-02 T
 * +e) 4.002E-02 T

3) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * -a) 6.807E-05 T-m
 * -b) 7.487E-05 T-m
 * +c) 8.236E-05 T-m
 * -d) 9.060E-05 T-m
 * -e) 9.966E-05 T-m

4) A wire carries a current of 343 A in a circular arc with radius 2.95 cm swept through 38 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 1.902E+00 Tesla
 * -b) 2.092E+00 Tesla
 * -c) 2.301E+00 Tesla
 * +d) 2.532E+00 Tesla
 * -e) 2.785E+00 Tesla

Click these links for the keys:

Key: G1
1) Two loops of wire carry the same current of 97 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.595 m while the other has a radius of 1.1 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.63 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * +a) 5.302E-02 T
 * -b) 5.832E-02 T
 * -c) 6.415E-02 T
 * -d) 7.056E-02 T
 * -e) 7.762E-02 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.42 kA, I2=0.904 kA, and I3=1.34 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 2.696E-03 T-m
 * -b) 2.966E-03 T-m
 * -c) 3.263E-03 T-m
 * +d) 3.589E-03 T-m
 * -e) 3.948E-03 T-m

3) A wire carries a current of 293 A in a circular arc with radius 1.75 cm swept through 71 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 4.652E+00 Tesla
 * -b) 5.117E+00 Tesla
 * -c) 5.629E+00 Tesla
 * -d) 6.192E+00 Tesla
 * +e) 6.811E+00 Tesla

4) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * -a) 2.176E-04 T-m
 * -b) 2.393E-04 T-m
 * +c) 2.633E-04 T-m
 * -d) 2.896E-04 T-m
 * -e) 3.186E-04 T-m

Click these links for the keys:

Key: G2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.72 kA, I2=2.17 kA, and I3=3.21 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.905E-03 T-m
 * -b) 4.295E-03 T-m
 * +c) 4.725E-03 T-m
 * -d) 5.197E-03 T-m
 * -e) 5.717E-03 T-m

2) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * -a) 2.176E-04 T-m
 * -b) 2.393E-04 T-m
 * +c) 2.633E-04 T-m
 * -d) 2.896E-04 T-m
 * -e) 3.186E-04 T-m

3) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * -a) 7.952E-03 T
 * -b) 8.747E-03 T
 * -c) 9.622E-03 T
 * -d) 1.058E-02 T
 * +e) 1.164E-02 T

4) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 5.034E+00 Tesla
 * -b) 5.538E+00 Tesla
 * -c) 6.091E+00 Tesla
 * -d) 6.701E+00 Tesla
 * -e) 7.371E+00 Tesla

Click these links for the keys:

Key: H0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.432 m and $$B_{max}=\,$$ 0.402 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.275 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.277E+05 A
 * -b) 3.604E+05 A
 * -c) 3.965E+05 A
 * -d) 4.361E+05 A
 * +e) 4.797E+05 A

2) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

3) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 3.480E-05 T
 * -b) By= 3.828E-05 T
 * -c) By= 4.210E-05 T
 * -d) By= 4.631E-05 T
 * +e) By= 5.095E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.89 kA, I2=1.19 kA, and I3=3.5 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 6.535E-03 T-m
 * -b) 7.188E-03 T-m
 * -c) 7.907E-03 T-m
 * -d) 8.697E-03 T-m
 * -e) 9.567E-03 T-m

Click these links for the keys:

Key: H1
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 7.876E+05 A
 * -b) 8.664E+05 A
 * -c) 9.530E+05 A
 * -d) 1.048E+06 A
 * -e) 1.153E+06 A

2) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 3.480E-05 T
 * -b) By= 3.828E-05 T
 * -c) By= 4.210E-05 T
 * -d) By= 4.631E-05 T
 * +e) By= 5.095E-05 T

3) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 4.559E-05 T
 * -b) Bx= 5.015E-05 T
 * -c) Bx= 5.517E-05 T
 * -d) Bx= 6.068E-05 T
 * +e) Bx= 6.675E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=0.839 kA, and I3=2.27 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.354E-03 T-m
 * +b) 4.789E-03 T-m
 * -c) 5.268E-03 T-m
 * -d) 5.795E-03 T-m
 * -e) 6.374E-03 T-m

Click these links for the keys:

Key: H2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.57 kA, I2=0.708 kA, and I3=1.48 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 4.200E-03 T-m
 * -b) 4.620E-03 T-m
 * -c) 5.082E-03 T-m
 * -d) 5.590E-03 T-m
 * -e) 6.149E-03 T-m

2) Three wires sit at the corners of a square of length 0.699 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.87 A, 2.18 A, 1.34 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.999E-05 T
 * -b) By= 7.699E-05 T
 * +c) By= 8.469E-05 T
 * -d) By= 9.316E-05 T
 * -e) By= 1.025E-04 T

3) Three wires sit at the corners of a square of length 0.533 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.17 A, 2.25 A, 2.22 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 1.037E-04 T
 * -b) Bx= 1.141E-04 T
 * +c) Bx= 1.255E-04 T
 * -d) Bx= 1.381E-04 T
 * -e) Bx= 1.519E-04 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.259 m and $$B_{max}=\,$$ 0.575 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.191 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.492E+05 A
 * -b) 3.841E+05 A
 * -c) 4.225E+05 A
 * -d) 4.648E+05 A
 * +e) 5.113E+05 A

Click these links for the keys:

Key: I0
1) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * -a) 4.799E-02 T
 * -b) 5.278E-02 T
 * +c) 5.806E-02 T
 * -d) 6.387E-02 T
 * -e) 7.026E-02 T

2) Two parallel wires each carry a 7.68 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.36 cm, 1.58 cm), while the other is located at (5.29 cm, 5.18 cm). What is the force per unit length between the wires?


 * -a) 1.973E-10 N/m
 * -b) 2.170E-10 N/m
 * -c) 2.387E-10 N/m
 * -d) 2.625E-10 N/m
 * +e) 2.888E-10 N/m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.32 kA, I2=2.0 kA, and I3=3.66 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.724E-03 T-m
 * -b) 1.896E-03 T-m
 * +c) 2.086E-03 T-m
 * -d) 2.295E-03 T-m
 * -e) 2.524E-03 T-m

4) Three wires sit at the corners of a square of length 0.687 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.38 A, 1.87 A, 2.03 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.134E-05 T
 * -b) Bx= 7.847E-05 T
 * +c) Bx= 8.632E-05 T
 * -d) Bx= 9.495E-05 T
 * -e) Bx= 1.044E-04 T

Click these links for the keys:

Key: I1
1) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * -a) 2.634E-11 N/m
 * -b) 2.897E-11 N/m
 * +c) 3.187E-11 N/m
 * -d) 3.506E-11 N/m
 * -e) 3.856E-11 N/m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=2.33 kA, and I3=5.35 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 3.795E-03 T-m
 * -b) 4.175E-03 T-m
 * -c) 4.592E-03 T-m
 * -d) 5.051E-03 T-m
 * -e) 5.556E-03 T-m

3) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 8.371E-05 T
 * -b) Bx= 9.208E-05 T
 * +c) Bx= 1.013E-04 T
 * -d) Bx= 1.114E-04 T
 * -e) Bx= 1.226E-04 T

4) Two loops of wire carry the same current of 85 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.854 m while the other has a radius of 1.18 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.5 m from the first (smaller) loopif the disance between the loops is 1.66 m?


 * -a) 4.253E-02 T
 * -b) 4.678E-02 T
 * -c) 5.146E-02 T
 * +d) 5.661E-02 T
 * -e) 6.227E-02 T

Click these links for the keys:

Key: I2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.547E-03 T-m
 * -b) 1.702E-03 T-m
 * +c) 1.872E-03 T-m
 * -d) 2.060E-03 T-m
 * -e) 2.266E-03 T-m

2) Two loops of wire carry the same current of 85 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.854 m while the other has a radius of 1.18 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.5 m from the first (smaller) loopif the disance between the loops is 1.66 m?


 * -a) 4.253E-02 T
 * -b) 4.678E-02 T
 * -c) 5.146E-02 T
 * +d) 5.661E-02 T
 * -e) 6.227E-02 T

3) Two parallel wires each carry a 4.15 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.19 cm, 1.78 cm), while the other is located at (3.73 cm, 4.12 cm). What is the force per unit length between the wires?


 * +a) 1.434E-10 N/m
 * -b) 1.578E-10 N/m
 * -c) 1.736E-10 N/m
 * -d) 1.909E-10 N/m
 * -e) 2.100E-10 N/m

4) Three wires sit at the corners of a square of length 0.688 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.73 A, 1.37 A, 1.65 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.171E-05 T
 * +b) Bx= 6.788E-05 T
 * -c) Bx= 7.467E-05 T
 * -d) Bx= 8.213E-05 T
 * -e) Bx= 9.035E-05 T

Click these links for the keys:

Key: J0
1) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * -a) 6.099E-03 T
 * -b) 6.709E-03 T
 * -c) 7.380E-03 T
 * -d) 8.118E-03 T
 * +e) 8.930E-03 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=2.33 kA, and I3=5.35 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 3.795E-03 T-m
 * -b) 4.175E-03 T-m
 * -c) 4.592E-03 T-m
 * -d) 5.051E-03 T-m
 * -e) 5.556E-03 T-m

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 4.028E-05 T
 * -b) By= 4.431E-05 T
 * -c) By= 4.874E-05 T
 * -d) By= 5.361E-05 T
 * -e) By= 5.897E-05 T

4) Two parallel wires each carry a 7.48 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.13 cm, 0.955 cm), while the other is located at (5.37 cm, 5.48 cm). What is the force per unit length between the wires?


 * -a) 2.015E-10 N/m
 * +b) 2.216E-10 N/m
 * -c) 2.438E-10 N/m
 * -d) 2.682E-10 N/m
 * -e) 2.950E-10 N/m

Click these links for the keys:

Key: J1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.51 kA, I2=1.32 kA, and I3=2.73 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.331E-03 T-m
 * -b) 1.464E-03 T-m
 * -c) 1.611E-03 T-m
 * +d) 1.772E-03 T-m
 * -e) 1.949E-03 T-m

2) Three wires sit at the corners of a square of length 0.76 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.91 A, 1.34 A, 1.05 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 5.611E-05 T
 * -b) By= 6.172E-05 T
 * +c) By= 6.789E-05 T
 * -d) By= 7.468E-05 T
 * -e) By= 8.215E-05 T

3) Two parallel wires each carry a 7.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.98 cm, 0.969 cm), while the other is located at (5.13 cm, 5.53 cm). What is the force per unit length between the wires?


 * -a) 1.840E-10 N/m
 * -b) 2.024E-10 N/m
 * -c) 2.227E-10 N/m
 * +d) 2.449E-10 N/m
 * -e) 2.694E-10 N/m

4) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * -a) 7.836E-03 T
 * -b) 8.620E-03 T
 * +c) 9.482E-03 T
 * -d) 1.043E-02 T
 * -e) 1.147E-02 T

Click these links for the keys:

Key: J2
1) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * -a) 1.127E-02 T
 * -b) 1.240E-02 T
 * -c) 1.364E-02 T
 * +d) 1.500E-02 T
 * -e) 1.650E-02 T

2) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.576E-05 T
 * +b) By= 8.333E-05 T
 * -c) By= 9.167E-05 T
 * -d) By= 1.008E-04 T
 * -e) By= 1.109E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 8.204E-04 T-m
 * -b) 9.025E-04 T-m
 * +c) 9.927E-04 T-m
 * -d) 1.092E-03 T-m
 * -e) 1.201E-03 T-m

4) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * -a) 2.449E-10 N/m
 * -b) 2.694E-10 N/m
 * -c) 2.963E-10 N/m
 * +d) 3.260E-10 N/m
 * -e) 3.586E-10 N/m

Click these links for the keys:

Key: K0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.57 kA, I2=0.708 kA, and I3=1.48 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 4.200E-03 T-m
 * -b) 4.620E-03 T-m
 * -c) 5.082E-03 T-m
 * -d) 5.590E-03 T-m
 * -e) 6.149E-03 T-m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=0.476 kA, and I3=1.57 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.250E-03 T-m
 * +b) 1.375E-03 T-m
 * -c) 1.512E-03 T-m
 * -d) 1.663E-03 T-m
 * -e) 1.830E-03 T-m

3) Two loops of wire carry the same current of 18 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.848 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.625 m from the first (smaller) loopif the disance between the loops is 1.55 m?


 * -a) 7.952E-03 T
 * -b) 8.747E-03 T
 * -c) 9.622E-03 T
 * -d) 1.058E-02 T
 * +e) 1.164E-02 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.171E+05 A
 * +b) 2.388E+05 A
 * -c) 2.627E+05 A
 * -d) 2.890E+05 A
 * -e) 3.179E+05 A

Click these links for the keys:

Key: K1
1) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * -a) 7.836E-03 T
 * -b) 8.620E-03 T
 * +c) 9.482E-03 T
 * -d) 1.043E-02 T
 * -e) 1.147E-02 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.547 m and $$B_{max}=\,$$ 0.597 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.158 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.751E+05 A
 * -b) 1.927E+05 A
 * -c) 2.119E+05 A
 * +d) 2.331E+05 A
 * -e) 2.564E+05 A

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.61 kA, I2=2.2 kA, and I3=5.1 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 3.644E-03 T-m
 * -b) 4.009E-03 T-m
 * -c) 4.410E-03 T-m
 * -d) 4.850E-03 T-m
 * -e) 5.336E-03 T-m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.38 kA, I2=1.58 kA, and I3=4.31 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.386E-03 T-m
 * -b) 4.825E-03 T-m
 * -c) 5.307E-03 T-m
 * -d) 5.838E-03 T-m
 * +e) 6.421E-03 T-m

Click these links for the keys:

Key: K2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 5.255E-03 T-m
 * -b) 5.781E-03 T-m
 * +c) 6.359E-03 T-m
 * -d) 6.994E-03 T-m
 * -e) 7.694E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.549 m and $$B_{max}=\,$$ 0.599 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.29 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 5.581E+05 A
 * -b) 6.139E+05 A
 * +c) 6.752E+05 A
 * -d) 7.428E+05 A
 * -e) 8.170E+05 A

3) Two loops of wire carry the same current of 44 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.678 m while the other has a radius of 1.14 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.508 m from the first (smaller) loopif the disance between the loops is 1.16 m?


 * -a) 3.342E-02 T
 * +b) 3.676E-02 T
 * -c) 4.044E-02 T
 * -d) 4.448E-02 T
 * -e) 4.893E-02 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.48 kA, I2=1.47 kA, and I3=2.6 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 1.420E-03 T-m
 * -b) 1.562E-03 T-m
 * -c) 1.718E-03 T-m
 * -d) 1.890E-03 T-m
 * -e) 2.079E-03 T-m

Click these links for the keys:

Key: L0
1) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * -a) 2.176E-04 T-m
 * -b) 2.393E-04 T-m
 * +c) 2.633E-04 T-m
 * -d) 2.896E-04 T-m
 * -e) 3.186E-04 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 1.208E-05 T
 * -b) 1.329E-05 T
 * -c) 1.462E-05 T
 * -d) 1.608E-05 T
 * -e) 1.769E-05 T

3) Three wires sit at the corners of a square of length 0.532 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.11 A, 1.25 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 5.930E-05 T
 * +b) By= 6.523E-05 T
 * -c) By= 7.175E-05 T
 * -d) By= 7.892E-05 T
 * -e) By= 8.682E-05 T

4) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * -a) 4.412E-10 N/m
 * +b) 4.853E-10 N/m
 * -c) 5.338E-10 N/m
 * -d) 5.872E-10 N/m
 * -e) 6.459E-10 N/m

Click these links for the keys:

Key: L1
1) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * -a) 2.977E-11 N/m
 * -b) 3.274E-11 N/m
 * -c) 3.602E-11 N/m
 * -d) 3.962E-11 N/m
 * +e) 4.358E-11 N/m

2) A solenoid has 7.690E+04 turns wound around a cylinder of diameter 1.63 cm and length 11 m. The current through the coils is 0.728 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.76 cm to z=+1.99 cm


 * -a) 2.762E-04 T-m
 * +b) 3.038E-04 T-m
 * -c) 3.342E-04 T-m
 * -d) 3.676E-04 T-m
 * -e) 4.043E-04 T-m

3) Three wires sit at the corners of a square of length 0.702 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.24 A, 1.37 A, 2.3 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.576E-05 T
 * +b) By= 8.333E-05 T
 * -c) By= 9.167E-05 T
 * -d) By= 1.008E-04 T
 * -e) By= 1.109E-04 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.51 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 1.098E-05 T
 * +b) 1.208E-05 T
 * -c) 1.329E-05 T
 * -d) 1.462E-05 T
 * -e) 1.608E-05 T

Click these links for the keys:

Key: L2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.64 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 1.920E-05 T
 * +b) 2.112E-05 T
 * -c) 2.323E-05 T
 * -d) 2.556E-05 T
 * -e) 2.811E-05 T

2) Three wires sit at the corners of a square of length 0.547 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.78 A, 1.34 A, 1.64 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.118E-05 T
 * -b) By= 6.730E-05 T
 * -c) By= 7.403E-05 T
 * -d) By= 8.144E-05 T
 * +e) By= 8.958E-05 T

3) A solenoid has 5.500E+04 turns wound around a cylinder of diameter 1.45 cm and length 15 m. The current through the coils is 0.395 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.19 cm to z=+2.16 cm


 * -a) 7.894E-05 T-m
 * -b) 8.683E-05 T-m
 * -c) 9.551E-05 T-m
 * -d) 1.051E-04 T-m
 * +e) 1.156E-04 T-m

4) Two parallel wires each carry a 2.12 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.67 cm, 1.25 cm), while the other is located at (4.69 cm, 4.27 cm). What is the force per unit length between the wires?


 * -a) 2.119E-11 N/m
 * -b) 2.331E-11 N/m
 * -c) 2.564E-11 N/m
 * +d) 2.820E-11 N/m
 * -e) 3.102E-11 N/m

Click these links for the keys:

Key: M0
1) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 7.518E-05 T
 * -b) By= 8.270E-05 T
 * -c) By= 9.097E-05 T
 * -d) By= 1.001E-04 T
 * -e) By= 1.101E-04 T

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.35 kA, I2=0.809 kA, and I3=2.34 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.031E-03 T-m
 * -b) 4.434E-03 T-m
 * +c) 4.877E-03 T-m
 * -d) 5.365E-03 T-m
 * -e) 5.901E-03 T-m

3) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * -a) 1.564E-02 T
 * -b) 1.720E-02 T
 * -c) 1.892E-02 T
 * -d) 2.081E-02 T
 * +e) 2.289E-02 T

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * -a) 3.882E-10 N/m
 * -b) 4.270E-10 N/m
 * +c) 4.697E-10 N/m
 * -d) 5.167E-10 N/m
 * -e) 5.683E-10 N/m

Click these links for the keys:

Key: M1
1) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * -a) 1.564E-02 T
 * -b) 1.720E-02 T
 * -c) 1.892E-02 T
 * -d) 2.081E-02 T
 * +e) 2.289E-02 T

2) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.035E-05 T
 * -b) By= 7.739E-05 T
 * -c) By= 8.512E-05 T
 * +d) By= 9.364E-05 T
 * -e) By= 1.030E-04 T

3) Two parallel wires each carry a 2.83 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.15 cm, 1.13 cm), while the other is located at (5.14 cm, 4.22 cm). What is the force per unit length between the wires?


 * -a) 2.977E-11 N/m
 * -b) 3.274E-11 N/m
 * -c) 3.602E-11 N/m
 * -d) 3.962E-11 N/m
 * +e) 4.358E-11 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.33 kA, I2=0.741 kA, and I3=2.21 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.261E-03 T-m
 * -b) 3.587E-03 T-m
 * -c) 3.945E-03 T-m
 * -d) 4.340E-03 T-m
 * +e) 4.774E-03 T-m

Click these links for the keys:

Key: M2
1) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * -a) 7.836E-03 T
 * -b) 8.620E-03 T
 * +c) 9.482E-03 T
 * -d) 1.043E-02 T
 * -e) 1.147E-02 T

2) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 4.028E-05 T
 * -b) By= 4.431E-05 T
 * -c) By= 4.874E-05 T
 * -d) By= 5.361E-05 T
 * -e) By= 5.897E-05 T

3) Two parallel wires each carry a 7.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.62 cm, 1.31 cm), while the other is located at (4.63 cm, 5.53 cm). What is the force per unit length between the wires?


 * -a) 2.588E-10 N/m
 * +b) 2.847E-10 N/m
 * -c) 3.131E-10 N/m
 * -d) 3.444E-10 N/m
 * -e) 3.789E-10 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.770E-03 T-m
 * +b) 4.147E-03 T-m
 * -c) 4.562E-03 T-m
 * -d) 5.018E-03 T-m
 * -e) 5.520E-03 T-m

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Key: N0
1) Two loops of wire carry the same current of 11 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.424 m while the other has a radius of 1.32 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.52 m from the first (smaller) loopif the disance between the loops is 1.25 m?


 * +a) 7.623E-03 T
 * -b) 8.385E-03 T
 * -c) 9.223E-03 T
 * -d) 1.015E-02 T
 * -e) 1.116E-02 T

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.18 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 1.791E-05 T
 * -b) 1.970E-05 T
 * -c) 2.167E-05 T
 * -d) 2.384E-05 T
 * +e) 2.622E-05 T

3) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

4) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * -a) 1.121E-04 T-m
 * -b) 1.233E-04 T-m
 * +c) 1.356E-04 T-m
 * -d) 1.492E-04 T-m
 * -e) 1.641E-04 T-m

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Key: N1
1) A solenoid has 7.920E+04 turns wound around a cylinder of diameter 1.45 cm and length 11 m. The current through the coils is 0.702 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.27 cm to z=+1.36 cm


 * -a) 2.687E-04 T-m
 * -b) 2.955E-04 T-m
 * -c) 3.251E-04 T-m
 * +d) 3.576E-04 T-m
 * -e) 3.934E-04 T-m

2) Three wires sit at the corners of a square of length 0.796 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.48 A, 1.4 A, 1.47 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 4.506E-05 T
 * -b) Bx= 4.957E-05 T
 * +c) Bx= 5.452E-05 T
 * -d) Bx= 5.997E-05 T
 * -e) Bx= 6.597E-05 T

3) Two loops of wire carry the same current of 20 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.776 m while the other has a radius of 1.2 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.517 m from the first (smaller) loopif the disance between the loops is 1.37 m?


 * -a) 1.127E-02 T
 * -b) 1.240E-02 T
 * -c) 1.364E-02 T
 * +d) 1.500E-02 T
 * -e) 1.650E-02 T

4) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 3.33 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 2.202E-05 T
 * -b) 2.422E-05 T
 * +c) 2.664E-05 T
 * -d) 2.930E-05 T
 * -e) 3.223E-05 T

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Key: N2
1) A solenoid has 7.610E+04 turns wound around a cylinder of diameter 1.21 cm and length 9 m. The current through the coils is 0.696 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.52 cm to z=+2.04 cm


 * -a) 2.176E-04 T-m
 * -b) 2.393E-04 T-m
 * +c) 2.633E-04 T-m
 * -d) 2.896E-04 T-m
 * -e) 3.186E-04 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 2.26 mm from the center of a wire of radius 5 mm if the current is 1A?


 * -a) 1.494E-05 T
 * -b) 1.644E-05 T
 * +c) 1.808E-05 T
 * -d) 1.989E-05 T
 * -e) 2.188E-05 T

3) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 8.371E-05 T
 * -b) Bx= 9.208E-05 T
 * +c) Bx= 1.013E-04 T
 * -d) Bx= 1.114E-04 T
 * -e) Bx= 1.226E-04 T

4) Two loops of wire carry the same current of 99 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.798 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.394 m from the first (smaller) loopif the disance between the loops is 1.29 m?


 * +a) 8.291E-02 T
 * -b) 9.120E-02 T
 * -c) 1.003E-01 T
 * -d) 1.104E-01 T
 * -e) 1.214E-01 T

Click these links for the keys:

Key: O0
1) Three wires sit at the corners of a square of length 0.467 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.29 A, 1.77 A, 1.48 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 8.371E-05 T
 * -b) Bx= 9.208E-05 T
 * +c) Bx= 1.013E-04 T
 * -d) Bx= 1.114E-04 T
 * -e) Bx= 1.226E-04 T

2) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * -a) 1.121E-04 T-m
 * -b) 1.233E-04 T-m
 * +c) 1.356E-04 T-m
 * -d) 1.492E-04 T-m
 * -e) 1.641E-04 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.49 kA, I2=0.996 kA, and I3=2.61 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.385E-03 T-m
 * -b) 1.524E-03 T-m
 * -c) 1.676E-03 T-m
 * -d) 1.844E-03 T-m
 * +e) 2.028E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.51 m and $$B_{max}=\,$$ 0.649 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.376 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 9.388E+05 A
 * -b) 1.033E+06 A
 * +c) 1.136E+06 A
 * -d) 1.249E+06 A
 * -e) 1.374E+06 A

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Key: O1
1) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

2) A solenoid has 9.160E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.873 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;1.74 cm to z=+4.75 cm


 * -a) 3.369E-04 T-m
 * -b) 3.706E-04 T-m
 * +c) 4.076E-04 T-m
 * -d) 4.484E-04 T-m
 * -e) 4.932E-04 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 8.204E-04 T-m
 * -b) 9.025E-04 T-m
 * +c) 9.927E-04 T-m
 * -d) 1.092E-03 T-m
 * -e) 1.201E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

Click these links for the keys:

Key: O2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.171E+05 A
 * +b) 2.388E+05 A
 * -c) 2.627E+05 A
 * -d) 2.890E+05 A
 * -e) 3.179E+05 A

2) Three wires sit at the corners of a square of length 0.784 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.19 A, 1.51 A, 2.18 A), respectively. What is the x-component of the magnetic field at point P?


 * +a) Bx= 7.487E-05 T
 * -b) Bx= 8.236E-05 T
 * -c) Bx= 9.060E-05 T
 * -d) Bx= 9.966E-05 T
 * -e) Bx= 1.096E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.64 kA, and I3=4.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 2.721E-03 T-m
 * -b) 2.993E-03 T-m
 * -c) 3.292E-03 T-m
 * -d) 3.621E-03 T-m
 * +e) 3.984E-03 T-m

4) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * -a) 1.863E-04 T-m
 * +b) 2.050E-04 T-m
 * -c) 2.255E-04 T-m
 * -d) 2.480E-04 T-m
 * -e) 2.728E-04 T-m

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Key: P0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.547E-03 T-m
 * -b) 1.702E-03 T-m
 * +c) 1.872E-03 T-m
 * -d) 2.060E-03 T-m
 * -e) 2.266E-03 T-m

2) A wire carries a current of 303 A in a circular arc with radius 2.2 cm swept through 72 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 3.881E+00 Tesla
 * -b) 4.269E+00 Tesla
 * -c) 4.696E+00 Tesla
 * -d) 5.165E+00 Tesla
 * +e) 5.682E+00 Tesla

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 4.028E-05 T
 * -b) By= 4.431E-05 T
 * -c) By= 4.874E-05 T
 * -d) By= 5.361E-05 T
 * -e) By= 5.897E-05 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 18 turns per centimeter and the current applied to the solenoid is 582 mA, the net magnetic field is measured to be 1.15 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 7.211E+02
 * -b) $$\chi \text{ (chi) }=$$ 7.932E+02
 * +c) $$\chi \text{ (chi) }=$$ 8.726E+02
 * -d) $$\chi \text{ (chi) }=$$ 9.598E+02
 * -e) $$\chi \text{ (chi) }=$$ 1.056E+03

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Key: P1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=0.476 kA, and I3=1.57 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.250E-03 T-m
 * +b) 1.375E-03 T-m
 * -c) 1.512E-03 T-m
 * -d) 1.663E-03 T-m
 * -e) 1.830E-03 T-m

2) Three wires sit at the corners of a square of length 0.834 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.26 A, 1.75 A, 2.47 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 7.518E-05 T
 * -b) By= 8.270E-05 T
 * -c) By= 9.097E-05 T
 * -d) By= 1.001E-04 T
 * -e) By= 1.101E-04 T

3) A wire carries a current of 266 A in a circular arc with radius 2.21 cm swept through 73 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 5.034E+00 Tesla
 * -b) 5.538E+00 Tesla
 * -c) 6.091E+00 Tesla
 * -d) 6.701E+00 Tesla
 * -e) 7.371E+00 Tesla

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 359 mA, the net magnetic field is measured to be 1.32 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 1.124E+03
 * -b) $$\chi \text{ (chi) }=$$ 1.237E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.360E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.497E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.646E+03

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Key: P2
1) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 5.711E+00 Tesla
 * -b) 6.283E+00 Tesla
 * -c) 6.911E+00 Tesla
 * -d) 7.602E+00 Tesla
 * +e) 8.362E+00 Tesla

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.49 kA, I2=0.996 kA, and I3=2.61 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.385E-03 T-m
 * -b) 1.524E-03 T-m
 * -c) 1.676E-03 T-m
 * -d) 1.844E-03 T-m
 * +e) 2.028E-03 T-m

3) Three wires sit at the corners of a square of length 0.716 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.94 A, 2.04 A, 2.41 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.833E-05 T
 * -b) By= 7.517E-05 T
 * +c) By= 8.268E-05 T
 * -d) By= 9.095E-05 T
 * -e) By= 1.000E-04 T

4) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 359 mA, the net magnetic field is measured to be 1.32 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 1.124E+03
 * -b) $$\chi \text{ (chi) }=$$ 1.237E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.360E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.497E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.646E+03

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Key: Q0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=2.02 kA, and I3=4.24 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 5.255E-03 T-m
 * -b) 5.781E-03 T-m
 * +c) 6.359E-03 T-m
 * -d) 6.994E-03 T-m
 * -e) 7.694E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.55 kA, I2=1.02 kA, and I3=1.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 8.204E-04 T-m
 * -b) 9.025E-04 T-m
 * +c) 9.927E-04 T-m
 * -d) 1.092E-03 T-m
 * -e) 1.201E-03 T-m

4) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * -a) 4.412E-10 N/m
 * +b) 4.853E-10 N/m
 * -c) 5.338E-10 N/m
 * -d) 5.872E-10 N/m
 * -e) 6.459E-10 N/m

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Key: Q1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.66 kA, I2=1.25 kA, and I3=2.74 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.547E-03 T-m
 * -b) 1.702E-03 T-m
 * +c) 1.872E-03 T-m
 * -d) 2.060E-03 T-m
 * -e) 2.266E-03 T-m

2) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * -a) 1.422E-11 N/m
 * -b) 1.564E-11 N/m
 * -c) 1.720E-11 N/m
 * +d) 1.892E-11 N/m
 * -e) 2.081E-11 N/m

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.382E+05 A
 * +b) 3.720E+05 A
 * -c) 4.092E+05 A
 * -d) 4.502E+05 A
 * -e) 4.952E+05 A

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.770E-03 T-m
 * +b) 4.147E-03 T-m
 * -c) 4.562E-03 T-m
 * -d) 5.018E-03 T-m
 * -e) 5.520E-03 T-m

Click these links for the keys:

Key: Q2
1) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * -a) 2.634E-11 N/m
 * -b) 2.897E-11 N/m
 * +c) 3.187E-11 N/m
 * -d) 3.506E-11 N/m
 * -e) 3.856E-11 N/m

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.58 kA, I2=1.27 kA, and I3=1.99 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 3.770E-03 T-m
 * +b) 4.147E-03 T-m
 * -c) 4.562E-03 T-m
 * -d) 5.018E-03 T-m
 * -e) 5.520E-03 T-m

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.45 kA, I2=2.68 kA, and I3=5.5 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 3.544E-03 T-m
 * -b) 3.898E-03 T-m
 * -c) 4.288E-03 T-m
 * -d) 4.717E-03 T-m
 * -e) 5.188E-03 T-m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 5.479E+05 A
 * -b) 6.027E+05 A
 * -c) 6.630E+05 A
 * -d) 7.293E+05 A
 * -e) 8.022E+05 A

Click these links for the keys:

Key: R0
1) Two parallel wires each carry a 3.38 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.46 cm, 1.76 cm), while the other is located at (5.13 cm, 5.5 cm). What is the force per unit length between the wires?


 * -a) 3.810E-11 N/m
 * -b) 4.191E-11 N/m
 * -c) 4.610E-11 N/m
 * -d) 5.071E-11 N/m
 * +e) 5.578E-11 N/m

2) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * -a) 6.099E-03 T
 * -b) 6.709E-03 T
 * -c) 7.380E-03 T
 * -d) 8.118E-03 T
 * +e) 8.930E-03 T

3) Three wires sit at the corners of a square of length 0.688 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.73 A, 1.37 A, 1.65 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.171E-05 T
 * +b) Bx= 6.788E-05 T
 * -c) Bx= 7.467E-05 T
 * -d) Bx= 8.213E-05 T
 * -e) Bx= 9.035E-05 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.248 m and $$B_{max}=\,$$ 0.459 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.152 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.228E+05 A
 * -b) 2.451E+05 A
 * -c) 2.696E+05 A
 * +d) 2.966E+05 A
 * -e) 3.262E+05 A

Click these links for the keys:

Key: R1
1) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * -a) 2.449E-10 N/m
 * -b) 2.694E-10 N/m
 * -c) 2.963E-10 N/m
 * +d) 3.260E-10 N/m
 * -e) 3.586E-10 N/m

2) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 4.559E-05 T
 * -b) Bx= 5.015E-05 T
 * -c) Bx= 5.517E-05 T
 * -d) Bx= 6.068E-05 T
 * +e) Bx= 6.675E-05 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.253 m and $$B_{max}=\,$$ 0.489 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.112 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.289E+05 A
 * -b) 1.418E+05 A
 * -c) 1.560E+05 A
 * -d) 1.716E+05 A
 * +e) 1.888E+05 A

4) Two loops of wire carry the same current of 88 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.655 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.531 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * -a) 4.162E-02 T
 * -b) 4.578E-02 T
 * -c) 5.036E-02 T
 * +d) 5.540E-02 T
 * -e) 6.094E-02 T

Click these links for the keys:

Key: R2
1) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * -a) 5.926E-11 N/m
 * +b) 6.518E-11 N/m
 * -c) 7.170E-11 N/m
 * -d) 7.887E-11 N/m
 * -e) 8.676E-11 N/m

2) Two loops of wire carry the same current of 21 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.753 m while the other has a radius of 1.47 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.406 m from the first (smaller) loopif the disance between the loops is 1.38 m?


 * -a) 1.559E-02 T
 * +b) 1.715E-02 T
 * -c) 1.886E-02 T
 * -d) 2.075E-02 T
 * -e) 2.283E-02 T

3) Three wires sit at the corners of a square of length 0.51 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.16 A, 2.46 A, 2.15 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 9.053E-05 T
 * -b) Bx= 9.959E-05 T
 * -c) Bx= 1.095E-04 T
 * -d) Bx= 1.205E-04 T
 * +e) Bx= 1.325E-04 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

Click these links for the keys:

Key: S0
1) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 3.498E+00 Tesla
 * -b) 3.848E+00 Tesla
 * -c) 4.233E+00 Tesla
 * -d) 4.656E+00 Tesla
 * -e) 5.122E+00 Tesla

2) Two loops of wire carry the same current of 97 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.595 m while the other has a radius of 1.1 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.63 m from the first (smaller) loopif the disance between the loops is 1.72 m?


 * +a) 5.302E-02 T
 * -b) 5.832E-02 T
 * -c) 6.415E-02 T
 * -d) 7.056E-02 T
 * -e) 7.762E-02 T

3) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.718E-05 T
 * -b) By= 7.390E-05 T
 * +c) By= 8.129E-05 T
 * -d) By= 8.942E-05 T
 * -e) By= 9.836E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=3.3 kA, and I3=5.85 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 5.598E-03 T-m
 * -b) 6.158E-03 T-m
 * +c) 6.773E-03 T-m
 * -d) 7.451E-03 T-m
 * -e) 8.196E-03 T-m

Click these links for the keys:

Key: S1
1) Three wires sit at the corners of a square of length 0.591 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.47 A, 2.1 A, 2.24 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 1.191E-04 T
 * -b) By= 1.310E-04 T
 * -c) By= 1.441E-04 T
 * -d) By= 1.585E-04 T
 * -e) By= 1.744E-04 T

2) A wire carries a current of 338 A in a circular arc with radius 2.62 cm swept through 79 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 4.387E+00 Tesla
 * -b) 4.826E+00 Tesla
 * -c) 5.309E+00 Tesla
 * +d) 5.839E+00 Tesla
 * -e) 6.423E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.46 kA, I2=2.14 kA, and I3=4.44 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.943E-03 T-m
 * -b) 5.438E-03 T-m
 * +c) 5.982E-03 T-m
 * -d) 6.580E-03 T-m
 * -e) 7.238E-03 T-m

4) Two loops of wire carry the same current of 29 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.76 m while the other has a radius of 1.12 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.544 m from the first (smaller) loopif the disance between the loops is 1.56 m?


 * +a) 1.950E-02 T
 * -b) 2.145E-02 T
 * -c) 2.360E-02 T
 * -d) 2.596E-02 T
 * -e) 2.855E-02 T

Click these links for the keys:

Key: S2
1) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.718E-05 T
 * -b) By= 7.390E-05 T
 * +c) By= 8.129E-05 T
 * -d) By= 8.942E-05 T
 * -e) By= 9.836E-05 T

2) A wire carries a current of 353 A in a circular arc with radius 2.44 cm swept through 86 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 5.891E+00 Tesla
 * -b) 6.481E+00 Tesla
 * +c) 7.129E+00 Tesla
 * -d) 7.841E+00 Tesla
 * -e) 8.626E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.84 kA, I2=3.3 kA, and I3=5.85 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 5.598E-03 T-m
 * -b) 6.158E-03 T-m
 * +c) 6.773E-03 T-m
 * -d) 7.451E-03 T-m
 * -e) 8.196E-03 T-m

4) Two loops of wire carry the same current of 64 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.838 m while the other has a radius of 1.17 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.528 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * -a) 3.863E-02 T
 * +b) 4.249E-02 T
 * -c) 4.674E-02 T
 * -d) 5.141E-02 T
 * -e) 5.655E-02 T

Click these links for the keys:

Key: T0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.64 kA, and I3=4.81 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 2.721E-03 T-m
 * -b) 2.993E-03 T-m
 * -c) 3.292E-03 T-m
 * -d) 3.621E-03 T-m
 * +e) 3.984E-03 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.171E+05 A
 * +b) 2.388E+05 A
 * -c) 2.627E+05 A
 * -d) 2.890E+05 A
 * -e) 3.179E+05 A

3) Two parallel wires each carry a 6.53 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.82 cm, 1.17 cm), while the other is located at (4.07 cm, 5.5 cm). What is the force per unit length between the wires?


 * -a) 1.788E-10 N/m
 * +b) 1.966E-10 N/m
 * -c) 2.163E-10 N/m
 * -d) 2.379E-10 N/m
 * -e) 2.617E-10 N/m

4) A wire carries a current of 202 A in a circular arc with radius 2.17 cm swept through 51 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 2.473E+00 Tesla
 * +b) 2.720E+00 Tesla
 * -c) 2.992E+00 Tesla
 * -d) 3.291E+00 Tesla
 * -e) 3.620E+00 Tesla

Click these links for the keys:

Key: T1
1) A wire carries a current of 297 A in a circular arc with radius 2.31 cm swept through 75 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 3.774E+00 Tesla
 * -b) 4.151E+00 Tesla
 * -c) 4.566E+00 Tesla
 * -d) 5.023E+00 Tesla
 * +e) 5.525E+00 Tesla

2) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.08 kA, and I3=1.77 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 7.166E-04 T-m
 * -b) 7.883E-04 T-m
 * +c) 8.671E-04 T-m
 * -d) 9.538E-04 T-m
 * -e) 1.049E-03 T-m

3) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * -a) 1.283E-10 N/m
 * -b) 1.411E-10 N/m
 * -c) 1.552E-10 N/m
 * -d) 1.708E-10 N/m
 * +e) 1.878E-10 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.547 m and $$B_{max}=\,$$ 0.597 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.158 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.751E+05 A
 * -b) 1.927E+05 A
 * -c) 2.119E+05 A
 * +d) 2.331E+05 A
 * -e) 2.564E+05 A

Click these links for the keys:

Key: T2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

2) A wire carries a current of 303 A in a circular arc with radius 2.2 cm swept through 72 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 3.881E+00 Tesla
 * -b) 4.269E+00 Tesla
 * -c) 4.696E+00 Tesla
 * -d) 5.165E+00 Tesla
 * +e) 5.682E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.43 kA, I2=1.81 kA, and I3=3.23 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.622E-03 T-m
 * +b) 1.784E-03 T-m
 * -c) 1.963E-03 T-m
 * -d) 2.159E-03 T-m
 * -e) 2.375E-03 T-m

4) Two parallel wires each carry a 8.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.66 cm, 1.4 cm), while the other is located at (5.64 cm, 5.66 cm). What is the force per unit length between the wires?


 * -a) 2.449E-10 N/m
 * -b) 2.694E-10 N/m
 * -c) 2.963E-10 N/m
 * +d) 3.260E-10 N/m
 * -e) 3.586E-10 N/m

Click these links for the keys:

Key: U0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.407 m and $$B_{max}=\,$$ 0.605 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.583E+05 A
 * -b) 3.941E+05 A
 * +c) 4.335E+05 A
 * -d) 4.769E+05 A
 * -e) 5.246E+05 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 20 turns per centimeter and the current applied to the solenoid is 344 mA, the net magnetic field is measured to be 1.24 T. What is the magnetic susceptibility for this case?


 * -a) $$\chi \text{ (chi) }=$$ 1.185E+03
 * -b) $$\chi \text{ (chi) }=$$ 1.303E+03
 * +c) $$\chi \text{ (chi) }=$$ 1.433E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.577E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.734E+03

3) Two parallel wires each carry a 4.15 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.19 cm, 1.78 cm), while the other is located at (3.73 cm, 4.12 cm). What is the force per unit length between the wires?


 * +a) 1.434E-10 N/m
 * -b) 1.578E-10 N/m
 * -c) 1.736E-10 N/m
 * -d) 1.909E-10 N/m
 * -e) 2.100E-10 N/m

4) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * -a) 1.121E-04 T-m
 * -b) 1.233E-04 T-m
 * +c) 1.356E-04 T-m
 * -d) 1.492E-04 T-m
 * -e) 1.641E-04 T-m

Click these links for the keys:

Key: U1
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 26 turns per centimeter and the current applied to the solenoid is 533 mA, the net magnetic field is measured to be 1.31 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 7.512E+02
 * -b) $$\chi \text{ (chi) }=$$ 8.264E+02
 * -c) $$\chi \text{ (chi) }=$$ 9.090E+02
 * -d) $$\chi \text{ (chi) }=$$ 9.999E+02
 * -e) $$\chi \text{ (chi) }=$$ 1.100E+03

3) A solenoid has 7.690E+04 turns wound around a cylinder of diameter 1.63 cm and length 11 m. The current through the coils is 0.728 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.76 cm to z=+1.99 cm


 * -a) 2.762E-04 T-m
 * +b) 3.038E-04 T-m
 * -c) 3.342E-04 T-m
 * -d) 3.676E-04 T-m
 * -e) 4.043E-04 T-m

4) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * -a) 1.283E-10 N/m
 * -b) 1.411E-10 N/m
 * -c) 1.552E-10 N/m
 * -d) 1.708E-10 N/m
 * +e) 1.878E-10 N/m

Click these links for the keys:

Key: U2
1) A solenoid has 5.160E+04 turns wound around a cylinder of diameter 1.55 cm and length 18 m. The current through the coils is 0.57 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.88 cm to z=+1.52 cm


 * -a) 6.788E-05 T-m
 * -b) 7.467E-05 T-m
 * -c) 8.213E-05 T-m
 * +d) 9.035E-05 T-m
 * -e) 9.938E-05 T-m

2) A long coil is tightly wound around a (hypothetical) ferromagnetic cylinder. If n= 27 turns per centimeter and the current applied to the solenoid is 280 mA, the net magnetic field is measured to be 1.13 T. What is the magnetic susceptibility for this case?


 * +a) $$\chi \text{ (chi) }=$$ 1.188E+03
 * -b) $$\chi \text{ (chi) }=$$ 1.307E+03
 * -c) $$\chi \text{ (chi) }=$$ 1.438E+03
 * -d) $$\chi \text{ (chi) }=$$ 1.582E+03
 * -e) $$\chi \text{ (chi) }=$$ 1.740E+03

3) Two parallel wires each carry a 2.58 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.79 cm, 1.03 cm), while the other is located at (5.64 cm, 5.12 cm). What is the force per unit length between the wires?


 * -a) 2.634E-11 N/m
 * -b) 2.897E-11 N/m
 * +c) 3.187E-11 N/m
 * -d) 3.506E-11 N/m
 * -e) 3.856E-11 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.852 m and $$B_{max}=\,$$ 0.476 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.212 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.502E+05 A
 * -b) 1.652E+05 A
 * -c) 1.817E+05 A
 * -d) 1.999E+05 A
 * +e) 2.199E+05 A

Click these links for the keys:

Key: V0
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 5.479E+05 A
 * -b) 6.027E+05 A
 * -c) 6.630E+05 A
 * -d) 7.293E+05 A
 * -e) 8.022E+05 A

2) Two loops of wire carry the same current of 14 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.835 m while the other has a radius of 1.29 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.607 m from the first (smaller) loopif the disance between the loops is 1.61 m?


 * -a) 6.099E-03 T
 * -b) 6.709E-03 T
 * -c) 7.380E-03 T
 * -d) 8.118E-03 T
 * +e) 8.930E-03 T

3) A solenoid has 4.730E+04 turns wound around a cylinder of diameter 1.46 cm and length 15 m. The current through the coils is 0.754 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.4 cm to z=+1.14 cm


 * -a) 1.121E-04 T-m
 * -b) 1.233E-04 T-m
 * +c) 1.356E-04 T-m
 * -d) 1.492E-04 T-m
 * -e) 1.641E-04 T-m

4) Three wires sit at the corners of a square of length 0.716 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.94 A, 2.04 A, 2.41 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.833E-05 T
 * -b) By= 7.517E-05 T
 * +c) By= 8.268E-05 T
 * -d) By= 9.095E-05 T
 * -e) By= 1.000E-04 T

Click these links for the keys:

Key: V1
1) A solenoid has 9.560E+04 turns wound around a cylinder of diameter 1.18 cm and length 12 m. The current through the coils is 0.664 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.49 cm to z=+3.61 cm


 * -a) 4.895E-04 T-m
 * +b) 5.384E-04 T-m
 * -c) 5.923E-04 T-m
 * -d) 6.515E-04 T-m
 * -e) 7.167E-04 T-m

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 7.876E+05 A
 * -b) 8.664E+05 A
 * -c) 9.530E+05 A
 * -d) 1.048E+06 A
 * -e) 1.153E+06 A

3) Three wires sit at the corners of a square of length 0.859 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.07 A, 1.32 A, 2.03 A), respectively. What is the y-component of the magnetic field at point P?


 * +a) By= 4.028E-05 T
 * -b) By= 4.431E-05 T
 * -c) By= 4.874E-05 T
 * -d) By= 5.361E-05 T
 * -e) By= 5.897E-05 T

4) Two loops of wire carry the same current of 39 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.49 m while the other has a radius of 1.11 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.552 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * -a) 1.564E-02 T
 * -b) 1.720E-02 T
 * -c) 1.892E-02 T
 * -d) 2.081E-02 T
 * +e) 2.289E-02 T

Click these links for the keys:

Key: V2
1) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 5.479E+05 A
 * -b) 6.027E+05 A
 * -c) 6.630E+05 A
 * -d) 7.293E+05 A
 * -e) 8.022E+05 A

2) Three wires sit at the corners of a square of length 0.793 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.32 A, 1.4 A, 2.27 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 3.480E-05 T
 * -b) By= 3.828E-05 T
 * -c) By= 4.210E-05 T
 * -d) By= 4.631E-05 T
 * +e) By= 5.095E-05 T

3) A solenoid has 5.980E+04 turns wound around a cylinder of diameter 1.8 cm and length 17 m. The current through the coils is 0.933 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;3.68 cm to z=+1.29 cm


 * -a) 1.863E-04 T-m
 * +b) 2.050E-04 T-m
 * -c) 2.255E-04 T-m
 * -d) 2.480E-04 T-m
 * -e) 2.728E-04 T-m

4) Two loops of wire carry the same current of 12 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.751 m while the other has a radius of 1.42 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.493 m from the first (smaller) loopif the disance between the loops is 1.26 m?


 * -a) 7.836E-03 T
 * -b) 8.620E-03 T
 * +c) 9.482E-03 T
 * -d) 1.043E-02 T
 * -e) 1.147E-02 T

Click these links for the keys:

Key: W0
1) Two loops of wire carry the same current of 64 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.838 m while the other has a radius of 1.17 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.528 m from the first (smaller) loopif the disance between the loops is 1.62 m?


 * -a) 3.863E-02 T
 * +b) 4.249E-02 T
 * -c) 4.674E-02 T
 * -d) 5.141E-02 T
 * -e) 5.655E-02 T

2) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * -a) 4.412E-10 N/m
 * +b) 4.853E-10 N/m
 * -c) 5.338E-10 N/m
 * -d) 5.872E-10 N/m
 * -e) 6.459E-10 N/m

3) Three wires sit at the corners of a square of length 0.823 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.41 A, 1.87 A, 2.21 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.718E-05 T
 * -b) By= 7.390E-05 T
 * +c) By= 8.129E-05 T
 * -d) By= 8.942E-05 T
 * -e) By= 9.836E-05 T

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.353 m and $$B_{max}=\,$$ 0.697 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.196 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 5.479E+05 A
 * -b) 6.027E+05 A
 * -c) 6.630E+05 A
 * -d) 7.293E+05 A
 * -e) 8.022E+05 A

Click these links for the keys:

Key: W1
1) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.035E-05 T
 * -b) By= 7.739E-05 T
 * -c) By= 8.512E-05 T
 * +d) By= 9.364E-05 T
 * -e) By= 1.030E-04 T

2) Two loops of wire carry the same current of 29 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.76 m while the other has a radius of 1.12 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.544 m from the first (smaller) loopif the disance between the loops is 1.56 m?


 * +a) 1.950E-02 T
 * -b) 2.145E-02 T
 * -c) 2.360E-02 T
 * -d) 2.596E-02 T
 * -e) 2.855E-02 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.37 m and $$B_{max}=\,$$ 0.556 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.14 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.171E+05 A
 * +b) 2.388E+05 A
 * -c) 2.627E+05 A
 * -d) 2.890E+05 A
 * -e) 3.179E+05 A

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * -a) 3.882E-10 N/m
 * -b) 4.270E-10 N/m
 * +c) 4.697E-10 N/m
 * -d) 5.167E-10 N/m
 * -e) 5.683E-10 N/m

Click these links for the keys:

Key: W2
1) Three wires sit at the corners of a square of length 0.534 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.45 A, 2.44 A, 1.61 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 9.388E-05 T
 * -b) By= 1.033E-04 T
 * -c) By= 1.136E-04 T
 * -d) By= 1.250E-04 T
 * +e) By= 1.375E-04 T

2) Two loops of wire carry the same current of 67 kA, and flow in the same direction. They share a common axis and orientation.  One loop has a radius of 0.847 m while the other has a radius of 1.15 m.  What is the magnitude of the magnetic field at a point on the axis of both loops, situated between the loops at a distance 0.408 m from the first (smaller) loopif the disance between the loops is 1.15 m?


 * -a) 4.799E-02 T
 * -b) 5.278E-02 T
 * +c) 5.806E-02 T
 * -d) 6.387E-02 T
 * -e) 7.026E-02 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.619 m and $$B_{max}=\,$$ 0.215 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.351 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 2.534E+05 A
 * -b) 2.787E+05 A
 * +c) 3.066E+05 A
 * -d) 3.373E+05 A
 * -e) 3.710E+05 A

4) Two parallel wires each carry a 7.75 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.62 cm, 1.31 cm), while the other is located at (4.63 cm, 5.53 cm). What is the force per unit length between the wires?


 * -a) 2.588E-10 N/m
 * +b) 2.847E-10 N/m
 * -c) 3.131E-10 N/m
 * -d) 3.444E-10 N/m
 * -e) 3.789E-10 N/m

Click these links for the keys:

Key: X0
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.32 kA, I2=2.0 kA, and I3=3.66 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.724E-03 T-m
 * -b) 1.896E-03 T-m
 * +c) 2.086E-03 T-m
 * -d) 2.295E-03 T-m
 * -e) 2.524E-03 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 3.324E-05 T
 * -b) 3.657E-05 T
 * +c) 4.022E-05 T
 * -d) 4.424E-05 T
 * -e) 4.867E-05 T

3) Two parallel wires each carry a 9.59 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.97 cm, 1.4 cm), while the other is located at (4.02 cm, 5.19 cm). What is the force per unit length between the wires?


 * -a) 4.412E-10 N/m
 * +b) 4.853E-10 N/m
 * -c) 5.338E-10 N/m
 * -d) 5.872E-10 N/m
 * -e) 6.459E-10 N/m

4) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.852 m and $$B_{max}=\,$$ 0.476 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.212 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 1.502E+05 A
 * -b) 1.652E+05 A
 * -c) 1.817E+05 A
 * -d) 1.999E+05 A
 * +e) 2.199E+05 A

Click these links for the keys:

Key: X1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.4 kA, I2=2.64 kA, and I3=3.96 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.133E-03 T-m
 * -b) 1.246E-03 T-m
 * -c) 1.371E-03 T-m
 * -d) 1.508E-03 T-m
 * +e) 1.659E-03 T-m

2) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.81 mm from the center of a wire of radius 3 mm if the current is 1A?


 * -a) 3.324E-05 T
 * -b) 3.657E-05 T
 * +c) 4.022E-05 T
 * -d) 4.424E-05 T
 * -e) 4.867E-05 T

3) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.568 m and $$B_{max}=\,$$ 0.214 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.387 m that is centered on the axis with its plane perpendicular to the axis?


 * -a) 3.382E+05 A
 * +b) 3.720E+05 A
 * -c) 4.092E+05 A
 * -d) 4.502E+05 A
 * -e) 4.952E+05 A

4) Two parallel wires each carry a 9.08 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.17 cm, 1.32 cm), while the other is located at (5.72 cm, 4.47 cm). What is the force per unit length between the wires?


 * -a) 3.882E-10 N/m
 * -b) 4.270E-10 N/m
 * +c) 4.697E-10 N/m
 * -d) 5.167E-10 N/m
 * -e) 5.683E-10 N/m

Click these links for the keys:

Key: X2
1) Under most conditions the current is distributed uniformly over the cross section of the wire.  What is the magnetic field 1.86 mm from the center of a wire of radius 5 mm if the current is 1A?


 * +a) 1.488E-05 T
 * -b) 1.637E-05 T
 * -c) 1.800E-05 T
 * -d) 1.981E-05 T
 * -e) 2.179E-05 T

2) The Z-pinch is an (often unstable) cylindrical plasma in which a aximuthal magnetic field is produced by a current in the z direction. A simple model for the magnetic field, valid for $$r<a$$ is, $$B_\theta (r)=\left( \frac{2r}{a} - \frac{r^2}{a^2}\right)B_{max}$$, where $$B_{max}$$ is the maximum magnetic field (at $$r=a$$).  If $$a=$$ 0.52 m and $$B_{max}=\,$$ 0.657 T, then how much current (in the z-direction) flows through a circle of radius $$r=$$ 0.295 m that is centered on the axis with its plane perpendicular to the axis?


 * +a) 7.876E+05 A
 * -b) 8.664E+05 A
 * -c) 9.530E+05 A
 * -d) 1.048E+06 A
 * -e) 1.153E+06 A

3) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * -a) 1.283E-10 N/m
 * -b) 1.411E-10 N/m
 * -c) 1.552E-10 N/m
 * -d) 1.708E-10 N/m
 * +e) 1.878E-10 N/m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.44 kA, I2=1.1 kA, and I3=1.99 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 1.017E-03 T-m
 * +b) 1.118E-03 T-m
 * -c) 1.230E-03 T-m
 * -d) 1.353E-03 T-m
 * -e) 1.489E-03 T-m

Click these links for the keys:

Key: Y0
1) Three wires sit at the corners of a square of length 0.66 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.18 A, 1.82 A, 1.35 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 7.035E-05 T
 * -b) By= 7.739E-05 T
 * -c) By= 8.512E-05 T
 * +d) By= 9.364E-05 T
 * -e) By= 1.030E-04 T

2) Two parallel wires each carry a 3.8 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.74 cm, 1.47 cm), while the other is located at (5.26 cm, 5.87 cm). What is the force per unit length between the wires?


 * -a) 5.926E-11 N/m
 * +b) 6.518E-11 N/m
 * -c) 7.170E-11 N/m
 * -d) 7.887E-11 N/m
 * -e) 8.676E-11 N/m

3) A solenoid has 3.950E+04 turns wound around a cylinder of diameter 1.64 cm and length 16 m. The current through the coils is 0.441 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.05 cm to z=+3.97 cm


 * -a) 6.807E-05 T-m
 * -b) 7.487E-05 T-m
 * +c) 8.236E-05 T-m
 * -d) 9.060E-05 T-m
 * -e) 9.966E-05 T-m

4) Three wires sit at the corners of a square of length 0.832 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.03 A, 1.95 A, 2.02 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 6.545E-05 T
 * +b) Bx= 7.200E-05 T
 * -c) Bx= 7.919E-05 T
 * -d) Bx= 8.711E-05 T
 * -e) Bx= 9.583E-05 T

Click these links for the keys:

Key: Y1
1) Two parallel wires each carry a 6.26 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (3.4 cm, 1.42 cm), while the other is located at (5.56 cm, 4.99 cm). What is the force per unit length between the wires?


 * -a) 1.283E-10 N/m
 * -b) 1.411E-10 N/m
 * -c) 1.552E-10 N/m
 * -d) 1.708E-10 N/m
 * +e) 1.878E-10 N/m

2) Three wires sit at the corners of a square of length 0.819 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.01 A, 1.09 A, 1.56 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 4.688E-05 T
 * -b) By= 5.156E-05 T
 * -c) By= 5.672E-05 T
 * +d) By= 6.239E-05 T
 * -e) By= 6.863E-05 T

3) Three wires sit at the corners of a square of length 0.686 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.28 A, 1.27 A, 1.61 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 5.409E-05 T
 * -b) Bx= 5.950E-05 T
 * +c) Bx= 6.545E-05 T
 * -d) Bx= 7.200E-05 T
 * -e) Bx= 7.920E-05 T

4) A solenoid has 4.900E+04 turns wound around a cylinder of diameter 1.74 cm and length 19 m. The current through the coils is 0.432 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;4.18 cm to z=+1.77 cm


 * -a) 6.884E-05 T-m
 * -b) 7.573E-05 T-m
 * +c) 8.330E-05 T-m
 * -d) 9.163E-05 T-m
 * -e) 1.008E-04 T-m

Click these links for the keys:

Key: Y2
1) Two parallel wires each carry a 1.65 mA current and are oriented in the z direction. The first wire is located in the x-y   plane at (4.59 cm, 1.81 cm), while the other is located at (5.78 cm, 4.43 cm). What is the force per unit length between the wires?


 * -a) 1.422E-11 N/m
 * -b) 1.564E-11 N/m
 * -c) 1.720E-11 N/m
 * +d) 1.892E-11 N/m
 * -e) 2.081E-11 N/m

2) A solenoid has 5.160E+04 turns wound around a cylinder of diameter 1.55 cm and length 18 m. The current through the coils is 0.57 A.  Define the origin to be the center of the solenoid and neglect end effects as you calculate the line integral $$\int\vec B\cdot\vec\ell$$ alongthe axis from z=&minus;2.88 cm to z=+1.52 cm


 * -a) 6.788E-05 T-m
 * -b) 7.467E-05 T-m
 * -c) 8.213E-05 T-m
 * +d) 9.035E-05 T-m
 * -e) 9.938E-05 T-m

3) Three wires sit at the corners of a square of length 0.547 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.78 A, 1.34 A, 1.64 A), respectively. What is the y-component of the magnetic field at point P?


 * -a) By= 6.118E-05 T
 * -b) By= 6.730E-05 T
 * -c) By= 7.403E-05 T
 * -d) By= 8.144E-05 T
 * +e) By= 8.958E-05 T

4) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

Click these links for the keys:

Key: Z0
1) A wire carries a current of 109 A in a circular arc with radius 1.26 cm swept through 71 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 2.908E+00 Tesla
 * -b) 3.199E+00 Tesla
 * +c) 3.519E+00 Tesla
 * -d) 3.871E+00 Tesla
 * -e) 4.258E+00 Tesla

2) Three wires sit at the corners of a square of length 0.784 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.19 A, 1.51 A, 2.18 A), respectively. What is the x-component of the magnetic field at point P?


 * +a) Bx= 7.487E-05 T
 * -b) Bx= 8.236E-05 T
 * -c) Bx= 9.060E-05 T
 * -d) Bx= 9.966E-05 T
 * -e) Bx= 1.096E-04 T

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.5 kA, I2=1.53 kA, and I3=2.34 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 1.018E-03 T-m
 * -b) 1.120E-03 T-m
 * -c) 1.232E-03 T-m
 * -d) 1.355E-03 T-m
 * -e) 1.490E-03 T-m

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.16 kA, and I3=2.13 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 2.815E-03 T-m
 * -b) 3.097E-03 T-m
 * -c) 3.406E-03 T-m
 * -d) 3.747E-03 T-m
 * +e) 4.122E-03 T-m

Click these links for the keys:

Key: Z1
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.31 kA, I2=1.16 kA, and I3=2.13 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 2.815E-03 T-m
 * -b) 3.097E-03 T-m
 * -c) 3.406E-03 T-m
 * -d) 3.747E-03 T-m
 * +e) 4.122E-03 T-m

2) A wire carries a current of 385 A in a circular arc with radius 1.53 cm swept through 58 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * -a) 5.711E+00 Tesla
 * -b) 6.283E+00 Tesla
 * -c) 6.911E+00 Tesla
 * -d) 7.602E+00 Tesla
 * +e) 8.362E+00 Tesla

3) Three wires sit at the corners of a square of length 0.785 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (2.23 A, 1.52 A, 1.86 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 4.559E-05 T
 * -b) Bx= 5.015E-05 T
 * -c) Bx= 5.517E-05 T
 * -d) Bx= 6.068E-05 T
 * +e) Bx= 6.675E-05 T

4) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.48 kA, I2=1.47 kA, and I3=2.6 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 1.420E-03 T-m
 * -b) 1.562E-03 T-m
 * -c) 1.718E-03 T-m
 * -d) 1.890E-03 T-m
 * -e) 2.079E-03 T-m

Click these links for the keys:

Key: Z2
1) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.5 kA, I2=1.28 kA, and I3=3.4 kA, take the $$\omega$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * -a) 4.362E-03 T-m
 * -b) 4.798E-03 T-m
 * -c) 5.278E-03 T-m
 * +d) 5.806E-03 T-m
 * -e) 6.386E-03 T-m

2) A wire carries a current of 250 A in a circular arc with radius 2.17 cm swept through 53 degrees. Assuming that the rest of the current is 100% shielded by  mu-metal, what is the magnetic field at the center of the arc?


 * +a) 3.498E+00 Tesla
 * -b) 3.848E+00 Tesla
 * -c) 4.233E+00 Tesla
 * -d) 4.656E+00 Tesla
 * -e) 5.122E+00 Tesla

3) The numbers (1,2,3) in the figure shown represent three currents flowing in or out of the page: I1 and I3 flow out of the page, and I2 flows into the page, as shown. Two closed paths are shown, labeled $$\beta$$ and $$\omega$$. If  I1=2.61 kA, I2=2.2 kA, and I3=5.1 kA, take the $$\beta$$ path and evalulate the line integral,    $$\oint\vec B\cdot d\vec\ell$$:


 * +a) 3.644E-03 T-m
 * -b) 4.009E-03 T-m
 * -c) 4.410E-03 T-m
 * -d) 4.850E-03 T-m
 * -e) 5.336E-03 T-m

4) Three wires sit at the corners of a square of length 0.774 cm. The currents all are in the positive-z direction (i.e. all come out of the paper in the figure shown.) The currents (I1, I2, I2) are (1.57 A, 2.03 A, 2.08 A), respectively. What is the x-component of the magnetic field at point P?


 * -a) Bx= 7.270E-05 T
 * +b) Bx= 7.997E-05 T
 * -c) Bx= 8.797E-05 T
 * -d) Bx= 9.677E-05 T
 * -e) Bx= 1.064E-04 T

Click these links for the keys: