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Deck 7: Sources of the Magnetic Field

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Question
A particle with charge q = 5 μ\mu C is moving with velocity <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px> . At t = 0, it is located at the origin. The magnetic field at <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px> at t = 0 is

A) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
B) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
C) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
D) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
E) None of these is correct.
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Question
<strong> A positively charged body is moving in the positive x direction as shown. The direction of the magnetic field at the origin due to the motion of this charged body is</strong> A) 1 B) 2 C) 3 D) 4 E) None of these is correct, as this charged body does not create a magnetic field along the axis of its motion. <div style=padding-top: 35px> A positively charged body is moving in the positive x direction as shown. The direction of the magnetic field at the origin due to the motion of this charged body is

A) 1
B) 2
C) 3
D) 4
E) None of these is correct, as this charged body does not create a magnetic field along the axis of its motion.
Question
The magnitude of the magnetic field due to the presence of a charged body

A) varies directly with the speed of the body.
B) varies directly with the charge carried by the body.
C) varies inversely with the square of the distance between the charged body and the field point.
D) depends on the magnetic properties of the space between the charged body and the field point.
E) is described by all of these.
Question
<strong> Two wires lying in the plane of this page carry equal currents in opposite directions, as shown. At a point midway between the wires, the magnetic field is</strong> A) zero. B) into the page. C) out of the page. D) toward the top or bottom of the page. E) toward one of the two wires. <div style=padding-top: 35px> Two wires lying in the plane of this page carry equal currents in opposite directions, as shown. At a point midway between the wires, the magnetic field is

A) zero.
B) into the page.
C) out of the page.
D) toward the top or bottom of the page.
E) toward one of the two wires.
Question
A point charge is moving with speed 2 *107 m/s along the x axis. At t = 0, the charge is at x = 0 m and the magnitude of the magnetic field at x = 4 m is B0. The magnitude of the magnetic field at x = 4m when t = 0.1 μ\mu s is

A) B0/2
B) B0
C) B0/4
D) 2B0
E) 4B0
Question
<strong> A positively charged body is moving in the negative z direction as shown. The direction of the magnetic field due to the motion of this charged body at point P is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> A positively charged body is moving in the negative z direction as shown. The direction of the magnetic field due to the motion of this charged body at point P is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
The top diagram shows the velocity of a positively charged particle. The direction of the magnetic field due to the moving charge at r is best represented by <strong>The top diagram shows the velocity of a positively charged particle. The direction of the magnetic field due to the moving charge at r is best represented by </strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px>

A) 1
B) 2
C) 3
D) 4
E) 5
Question
At a certain instant of time a particle with charge q = 25 μ\mu C is located at x = 4.0 m, y = 2.0 m; its velocity at that time is v = -20 m/s <strong>At a certain instant of time a particle with charge q = 25 \mu C is located at x = 4.0 m, y = 2.0 m; its velocity at that time is v = -20 m/s . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?</strong> A) 6.8 pT B) 1.1 pT C) 5.6 pT D) 2.2 pT E) 4.4 pT <div style=padding-top: 35px> . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?

A) 6.8 pT
B) 1.1 pT
C) 5.6 pT
D) 2.2 pT
E) 4.4 pT
Question
<strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px> A point charge of q1 = 5.8 nC is moving with speed 2.5 * 107 m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately

A) 0.70 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px>
B) -0.70 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px>
C) 3.2 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px>
D) -1.6 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px>
E) -0.35 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT <div style=padding-top: 35px>
Question
<strong> At the instant the positively charged body is at the origin, the magnetic field at point P due to the motion of this charged body is in the negative x direction. The charged body must be moving</strong> A) in the negative z direction. B) in the positive y direction. C) in the positive x direction. D) in the negative y direction. E) in the positive z direction. <div style=padding-top: 35px> At the instant the positively charged body is at the origin, the magnetic field at point P due to the motion of this charged body is in the negative x direction. The charged body must be moving

A) in the negative z direction.
B) in the positive y direction.
C) in the positive x direction.
D) in the negative y direction.
E) in the positive z direction.
Question
In a simple picture of the hydrogen atom, the electron moves in circular orbits around the central proton attracted by the Coulomb force. The lowest (n = 1) energy orbit that is allowed for the electron is at a radius of 5.29*10-11 m and the second (n = 2) lowest allowed orbit is at 4 times this radius. Calculate the magnetic field strength at the proton due to the orbital motion of the electron in the n = 2 state.

A) 0 T
B) 6.3 T
C) 0.39 T
D) 12.5 T
E) None of the above
Question
The Biot-Savart law is similar to Coulomb's law in that both

A) are inverse square laws.
B) include the permeability of free space.
C) deal with excess charges.
D) are not electrical in nature.
E) are described by none of the above.
Question
The magnetic field due to the presence of a charged body

A) depends on whether the charged body is moving.
B) depends on the direction the charged body is moving in relationship to the location of the field point.
C) varies inversely with the square of the distance between the charged body and the field point.
D) depends on the magnetic properties of the space between the charged body and the field point.
E) is described by all of these.
Question
In a simple picture of the hydrogen atom, the electron moves in circular orbits around the central proton attracted by the Coulomb force. The lowest (n = 1) energy orbit that is allowed for the electron is at a radius of 5.29 *10-11 m and the second (n = 2) lowest allowed orbit is at 4 times this radius. How many times stronger is the magnetic field strength at the proton due to the orbital motion of the electron in the n = 1 state than the n = 2 state?

A) 64
B) 16
C) 4
D) 1
E) 32
Question
<strong> At the instant the negatively charged body is at the origin, the magnetic field at point P due to its motion is in the negative x direction. The charged body must be moving</strong> A) in the negative z direction. B) in the positive y direction. C) in the positive x direction. D) in the negative y direction. E) in the positive z direction. <div style=padding-top: 35px> At the instant the negatively charged body is at the origin, the magnetic field at point P due to its motion is in the negative x direction. The charged body must be moving

A) in the negative z direction.
B) in the positive y direction.
C) in the positive x direction.
D) in the negative y direction.
E) in the positive z direction.
Question
A wire carries an electric current straight upward. What is the direction of the magnetic field due to the current north of the wire?

A) north
B) east
C) west
D) south
E) upward
Question
What is the direction of the magnetic field around a wire carrying a current perpendicularly into this page?

A) The field is parallel to and in the same direction as the current flow.
B) It is parallel to but directed opposite to the current flow.
C) It is counterclockwise around the wire in the plane of the page.
D) It is clockwise around the wire in the plane of the page.
E) None of these is correct.
Question
<strong> Two positively charged bodies are moving in opposite directions on parallel paths that lie in the xz plane. Their speeds are equal and their trajectories are equidistant from the x axis. The magnetic field at the origin, due to the motion of these charged bodies will be</strong> A) in the x direction. B) in the y direction. C) in all directions. D) in the z direction. E) zero. <div style=padding-top: 35px> Two positively charged bodies are moving in opposite directions on parallel paths that lie in the xz plane. Their speeds are equal and their trajectories are equidistant from the x axis. The magnetic field at the origin, due to the motion of these charged bodies will be

A) in the x direction.
B) in the y direction.
C) in all directions.
D) in the z direction.
E) zero.
Question
<strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px> A point charge of q1 = 3.6 nC is moving with speed 4.5 * 107 m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately

A) 0.39 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px>
B) -0.78 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px>
C) -0.39 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px>
D) 0.78 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px>
E) 2.0 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT <div style=padding-top: 35px>
Question
At a certain instant of time a particle with charge q = 15 μ\mu C is located at x = 2.0 m, y = 5.0 m; its velocity at that time is v = 40 m/s <strong>At a certain instant of time a particle with charge q = 15 \mu C is located at x = 2.0 m, y = 5.0 m; its velocity at that time is v = 40 m/s . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?</strong> A) 1.9 pT B) 3.8 pT C) 2.7 pT D) 4.1 pT E) 5.9 pT <div style=padding-top: 35px> . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?

A) 1.9 pT
B) 3.8 pT
C) 2.7 pT
D) 4.1 pT
E) 5.9 pT
Question
<strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is

A) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px>
B) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px>
C) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px>
D) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px>
E) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) <div style=padding-top: 35px>
Question
The magnetic field at a distance of 50 cm from a long, straight wire carrying a current of 5.0 A is approximately

A) 10 μ\mu T
B) 50 μ\mu T
C) 5.0 μ\mu T
D) 32 μ\mu T
E) 2.0 μ\mu T
Question
<strong> The sketch shows a circular coil in the xz plane carrying a current I. The direction of the magnetic field at point O is</strong> A) x B) -x C) y D) -y E) -z <div style=padding-top: 35px> The sketch shows a circular coil in the xz plane carrying a current I. The direction of the magnetic field at point O is

A) x
B) -x
C) y
D) -y
E) -z
Question
<strong> An electron beam travels counterclockwise in a circle in the magnetic field produced by the Helmholtz coils, as shown. Assuming that Earth's field is downward, one can conclude that</strong> A) the Helmholtz field equals Earth's field. B) the current in the coils moves in the same direction as the electron beam. C) the current in the coils moves in the direction opposite to the electron beam. D) the Helmholtz field curves in the direction of the electron beam. E) the Helmholtz field curves in a direction opposite to the electron beam. <div style=padding-top: 35px> An electron beam travels counterclockwise in a circle in the magnetic field produced by the Helmholtz coils, as shown. Assuming that Earth's field is downward, one can conclude that

A) the Helmholtz field equals Earth's field.
B) the current in the coils moves in the same direction as the electron beam.
C) the current in the coils moves in the direction opposite to the electron beam.
D) the Helmholtz field curves in the direction of the electron beam.
E) the Helmholtz field curves in a direction opposite to the electron beam.
Question
At great axial distances x from a current-carrying loop the magnetic field varies as

A) x2
B) x-3
C) x-2
D) x3
E) x-1
Question
<strong> The current in a wire along the x axis flows in the positive x direction. If a proton, located as shown in the figure, has an initial velocity in the positive z direction, it experiences</strong> A) a force in the direction of positive x. B) a force in the direction of negative x. C) a force in the direction of positive z. D) a force in the direction of positive y. E) no force. <div style=padding-top: 35px> The current in a wire along the x axis flows in the positive x direction. If a proton, located as shown in the figure, has an initial velocity in the positive z direction, it experiences

A) a force in the direction of positive x.
B) a force in the direction of negative x.
C) a force in the direction of positive z.
D) a force in the direction of positive y.
E) no force.
Question
A circular loop of wire 10 cm in radius carries a current of 20 A. The axial magnetic field 15 cm from the center of the loop is approximately

A) 37 μ\mu T
B) 13 μ\mu T
C) 21 μ\mu T
D) 41 μ\mu T
E) 18 μ\mu T
Question
<strong> A solenoid carries a current I. An electron is injected with velocity along the axis AB of the solenoid. When the electron is at C, it experiences a force that is</strong> A) zero. B) not zero and along AB. C) not zero and along BA. D) not zero and perpendicular to the page. E) None of these is correct. <div style=padding-top: 35px> A solenoid carries a current I. An electron is injected with velocity <strong> A solenoid carries a current I. An electron is injected with velocity along the axis AB of the solenoid. When the electron is at C, it experiences a force that is</strong> A) zero. B) not zero and along AB. C) not zero and along BA. D) not zero and perpendicular to the page. E) None of these is correct. <div style=padding-top: 35px> along the axis AB of the solenoid. When the electron is at C, it experiences a force that is

A) zero.
B) not zero and along AB.
C) not zero and along BA.
D) not zero and perpendicular to the page.
E) None of these is correct.
Question
<strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is

A) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px>
B) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px>
C) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px>
D) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px>
E) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) <div style=padding-top: 35px>
Question
When the positive current in a long wire is flowing in a direction from S to N, it creates a magnetic field below the wire that is directed

A) from E to W.
B) from N to S.
C) from NE to SW.
D) from S to N.
E) from W to E.
Question
<strong> Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( ) point in the direction of the negative x axis?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( <strong> Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( ) point in the direction of the negative x axis?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> ) point in the direction of the negative x axis?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
<strong> The graph that best represents the magnetic field B between the coils of radius R of a Helmholtz pair as a function of distance along the axis of the pair is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The graph that best represents the magnetic field B between the coils of radius R of a Helmholtz pair as a function of distance along the axis of the pair is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
In a circular loop of wire lying on a horizontal floor, the current is constant and, to a person looking downward, has a clockwise direction. The accompanying magnetic field at the center of the circle is directed

A) horizontally and to the east.
B) horizontally and to the north.
C) vertically upward.
D) parallel to the floor.
E) vertically downward.
Question
<strong> An electron beam travels counterclockwise in a circle of radius R in the magnetic field produced by the Helmholtz coils as shown. If you increase the current in the Helmholtz coils, the electron beam will</strong> A) increase its radius. B) decrease its radius. C) maintain the same radius. D) reverse and travel clockwise with the same radius. E) reverse and travel clockwise with a larger radius. <div style=padding-top: 35px> An electron beam travels counterclockwise in a circle of radius R in the magnetic field produced by the Helmholtz coils as shown. If you increase the current in the Helmholtz coils, the electron beam will

A) increase its radius.
B) decrease its radius.
C) maintain the same radius.
D) reverse and travel clockwise with the same radius.
E) reverse and travel clockwise with a larger radius.
Question
What is the magnetic field at the center of a circular loop with a diameter of 15.0 cm that carries a current of 1.50 A?

A) zero
B) 6.28 *10-6 T
C) 1.26 * 10-5 T
D) 2.51* 10-5 T
E) 1.68* 10-4 T
Question
A circular loop of wire of radius 6.0 cm has 30 turns and lies in the xy plane. It carries a current of 5 A in such a direction that the magnetic moment of the loop is along the x axis. The magnetic field on the x axis at x = 6.0 cm is approximately

A) 19 μ\mu T
B) 0.56 mT
C) 0.11 mT
D) 47 μ\mu T
E) 0.88 mT
Question
<strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is

A) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
B) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
C) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
D) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
E) None of these is correct.
Question
Two current-carrying wires are perpendicular to each other. The current in one flows vertically upward and the current in the other flows horizontally toward the east. The horizontal wire is 1 m south of the vertical wire. What is the direction of the net magnetic force on the horizontal wire?

A) north
B) east
C) west
D) south
E) There is no net magnetic force on the horizontal wire.
Question
A 1000-turn solenoid is 50 cm long and has a radius of 2.0 cm. It carries a current of 8.0 A. What is the magnetic field inside the solenoid near its center?

A) 2.0 * 10-2 T
B) 3.2 * 10-3 T
C) 4.0 * 10-4 T
D) 1.0 T
E) 2.0 * 10-4 T
Question
A circular loop of wire 1.0 cm in radius carries a current of 30 A. The magnetic field at the center of the loop is

A) 1.9 mT
B) 2.4 mT
C) 3.8 mT
D) 12 μ\mu T
E) 48 μ\mu T
Question
<strong> Two very long, parallel conducting wires carry equal currents in opposite directions. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> Two very long, parallel conducting wires carry equal currents in opposite directions. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Two straight rods 60 cm long and 2.0 mm apart in a current balance carry currents of 18 A each in opposite directions. What mass must be placed on the upper rod to balance the magnetic force of repulsion?

A) 0.50 g
B) 0.99 g
C) 9.7 g
D) 4.3 g
E) 1.6 g
Question
<strong> Two very long, parallel conducting wires carry equal currents in the same direction, as shown. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> Two very long, parallel conducting wires carry equal currents in the same direction, as shown. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
The force per unit length between two current-carrying wires is expressed as
F/l = ( μ\mu 0/2 π\pi d)I2
Where I is the current, d the separation of the wires, and l the length of each wire. A plot of force per unit length versus I2 gives a straight line, the slope of which is

A) μ\mu 0
B) F/l
C) (2 π\pi d/ μ\mu 0)1/2
D) μ\mu 0/2 π\pi d
E) FI2/l
Question
Two long, straight parallel wires 9.3 cm apart carry currents of equal magnitude I. They repel each other with a force per unit length of 5.8 nN/m. The current I is approximately

A) 27 mA
B) 65 mA
C) 43 mA
D) 52 mA
E) 2.7 mA
Question
<strong> Calculate the magnetic field at the center of a circular current loop of radius R divided by the magnetic field at a distance R away from a very long straight wire carrying the same current value I. (Note the loop and wire are not in electrical contact.)</strong> A) 3.14 B) 1.00 C) 2.00 D) 0.318 E) 0.500 <div style=padding-top: 35px> Calculate the magnetic field at the center of a circular current loop of radius R divided by the magnetic field at a distance R away from a very long straight wire carrying the same current value I. (Note the loop and wire are not in electrical contact.)

A) 3.14
B) 1.00
C) 2.00
D) 0.318
E) 0.500
Question
Calculate the magnetic field at the center of a circular current loop of area 0.200 m2 divided by the magnetic field at the center of a square current loop of the same inside area for the same current I value.

A) 1.00
B) 1.02
C) 0.246
D) 0.985
E) 0.785
Question
If the magnetic field at the center of a square current loop of side L = 40 cm is
2)4 *10-6 T calculate the current flowing around the loop.

A) 11 A
B) 3.4 A
C) 0.85 A
D) 0.21 A
E) 1.7 A
Question
<strong> Calculate the magnetic field and its direction at point P, which is 2.0 cm away from the top wire and 4.0 cm from the bottom wire. Assume both wires are infinitely long and each carries a current of 1.5 A.</strong> A) 2.3 *10<sup>-5</sup> T directed OUT of the page B) 7.5 *10<sup>-6</sup> T directed INTO the page C) 2.3 *10<sup>-5</sup> T directed INTO the page D) 7.5 * 10<sup>-6</sup> T directed OUT of the page E) 1.1 * 10<sup>-5</sup> T directed OUT of the page <div style=padding-top: 35px> Calculate the magnetic field and its direction at point P, which is 2.0 cm away from the top wire and 4.0 cm from the bottom wire. Assume both wires are infinitely long and each carries a current of 1.5 A.

A) 2.3 *10-5 T directed OUT of the page
B) 7.5 *10-6 T directed INTO the page
C) 2.3 *10-5 T directed INTO the page
D) 7.5 * 10-6 T directed OUT of the page
E) 1.1 * 10-5 T directed OUT of the page
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: -Two long parallel wires are a distance d apart (d = 6 cm) and carry equal and opposite currents of 5 A. Point P is distance d from each of the wires. Calculate the magnitude of the magnetic field strength at point P.</strong> A) 2.9 * 10<sup>-5</sup> T B) 8.5*10<sup>-6</sup> T C) 3.3 *10<sup>-5</sup> T D) 1.7* 10<sup>-5</sup> T E) none of the above <div style=padding-top: 35px>

-Two long parallel wires are a distance d apart (d = 6 cm) and carry equal and opposite currents of 5 A. Point P is distance d from each of the wires. Calculate the magnitude of the magnetic field strength at point P.

A) 2.9 * 10-5 T
B) 8.5*10-6 T
C) 3.3 *10-5 T
D) 1.7* 10-5 T
E) none of the above
Question
The two wires in a DC adapter cable are 5 mm apart and carry a current of 4 A. If the cable is 1.5 m long, calculate the force between the wires and state if this force is attractive or not.

A) 9.6 *10-4 N, attractive
B) 9.6 * 10-7 N, attractive
C) 1.1 * 10-8 N, attractive
D) 9.6 *10-4 N, repulsive
E) 1.1 *10-8 N, repulsive
Question
Two long, parallel wires are spaced 1 m apart in air, and you have established a current of 1 A in each. The force per unit length that each wire exerts on the other is

A) 4 μ\muπ\pi 0
B) 2 μ\muπ\pi 0
C) μ\mu 0
D) μ\mu 0/4 π\pi
E) μ\mu 0/2 π\pi
Question
Two long, straight parallel wires 7.6 cm apart carry currents of equal magnitude I. They attract each other with a force per unit length of 4.3 nN/m. The current I is approximately

A) 1.6 mA
B) 40 mA
C) 37 mA
D) 59 mA
E) 4.0 mA
Question
<strong> The graph that best represents the magnetic field on the axis inside a solenoid as a function of position x on the axis is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The graph that best represents the magnetic field on the axis inside a solenoid as a function of position x on the axis is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
<strong> The magnetic field at point P, due to the current in the very long wire, varies with distance R according to</strong> A) R<sup>2 </sup> B) R<sup>-3 </sup> C) R<sup>-2 </sup> D) R<sup>3 </sup> E) R<sup>-1 </sup> <div style=padding-top: 35px> The magnetic field at point P, due to the current in the very long wire, varies with distance R according to

A) R2
B) R-3
C) R-2
D) R3
E) R-1
Question
<strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is

A) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px>
B) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px>
C) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px>
D) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px>
E) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) <div style=padding-top: 35px>
Question
Two straight rods 55 cm long and 1.4 mm apart in a current balance carry current I, each in opposite directions. If a mass of 1.3 g when placed on the upper rod balances the magnetic force of repulsion between the rods, then calculate the current I.

A) 160 A
B) 18 A
C) 13 A
D) 3.6 A
E) 9.0 A
Question
Two long, parallel wires are spaced 1 m apart in air, and you have established a current of 1 A in each. The force per unit length that each wire exerts on the other is approximately

A) 2 * 10-6 N/m
B) 2 * 10-5 N/m
C) 2 * 10-7 N/m
D) 2 π\pi * 10-5 N/m
E) 2 π\pi * 10-6 N/m
Question
Two parallel wires carry currents I1 and I2 = 2I1 in the same direction. Which of the following expressions shows the relationship of the forces on the wires?

A) F1 = F2
B) F1 = 2F2
C) 2F1 = F2
D) F1 = 4F2
E) 4F1 = F2
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? </strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px>
Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? <strong>Use the following to answer the next question: Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? </strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px>

A) 1
B) 2
C) 3
D) 4
E) 5
Question
<strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> If the Biot-Savart relationship d <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> = ( μ\mu 0/4 π\pi )( <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> * <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> d <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> )/r3
Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> is correctly represented by

A) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> 1
B) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> 2
C) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> 3
D) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> 4
E) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> <div style=padding-top: 35px> 5
Question
A long straight wire of radius R carries a current density J = kr A/m2 where k is a constant. The magnetic field for r < R is (Hint: Current enclosed <strong>A long straight wire of radius R carries a current density J = kr A/m<sup>2</sup> where k is a constant. The magnetic field for r < R is (Hint: Current enclosed .)</strong> A) \mu <sub>0</sub>kr<sup>2</sup>/2 B) \mu <sub>0</sub>kr<sup>2</sup>/3 C) 2 \pi\mu <sub>0</sub>kr D) 2 \pi\mu <sub>0</sub>kr/2 E) none of the above <div style=padding-top: 35px> .)

A) μ\mu 0kr2/2
B) μ\mu 0kr2/3
C) 2 π\piμ\mu 0kr
D) 2 π\piμ\mu 0kr/2
E) none of the above
Question
A coaxial cable consists of a solid inner cylindrical conductor of radius 2 mm and an outer cylindrical shell of inner radius 3 mm and outer radius 3.5 mm. A current of 15 A flows down the inner wire and an equal return current flows in the outer conductor. If we assume that the currents are uniform over the cross section of the conductors, then calculate the magnitude of the enclosed current for use in Ampere's Law at a radius of 3.25 mm.

A) 7.2 A
B) 3.8 A
C) 7.8 A
D) 11.2 A
E) 7.5 A
Question
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field at the surface of the wire is approximately</strong> A) 8.4 mT B) 4.3 mT C) 6.7 mT D) 2.3 mT E) 5.7 mT <div style=padding-top: 35px> at the surface of the wire is approximately

A) 8.4 mT
B) 4.3 mT
C) 6.7 mT
D) 2.3 mT
E) 5.7 mT
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: -A coil of radius R = 5 cm lies inside a long solenoid which carries a current I<sub>1</sub> = 10 A and has 800 turns/m. The coil carries a current I<sub>2</sub> = 4 A and the normal of the plane of the coil is at an angle \theta = 30 \degree with the axis of the solenoid. The magnitude of the torque on the coil is</strong> A) 1.56 * 10<sup>-4</sup> N . m B) 2.74 * 10<sup>-4</sup> N . m C) 5.03 * 10<sup>-</sup><sup>5</sup> N . m D) 3.16 * 10<sup>-4</sup> N . m E) none of the above <div style=padding-top: 35px>

-A coil of radius R = 5 cm lies inside a long solenoid which carries a current I1 = 10 A and has 800 turns/m. The coil carries a current I2 = 4 A and the normal of the plane of the coil is at an angle θ\theta = 30 °\degree with the axis of the solenoid. The magnitude of the torque on the coil is

A) 1.56 * 10-4 N . m
B) 2.74 * 10-4 N . m
C) 5.03 * 10-5 N . m
D) 3.16 * 10-4 N . m
E) none of the above
Question
A wire of radius 0.6 cm carries a current of 10 A that is uniformly distributed over its cross section. Calculate the magnetic field strength at r = 0.2 cm divided by that at r = 0.4 cm.

A) 1.0
B) 0.75
C) 0.50
D) 2.0
E) 3.0
Question
A toroid has 200 turns of wire with a current of 3 A passing through the wire. The inner radius of the toroid is 3 cm and the outer radius is 5 cm. Calculate the magnetic field strength at a radius of 2 cm.

A) 6.0 * 10-3 T
B) 3.0 * 10-3 T
C) 1.2* 10-2 T
D) 4.8 F*10-4 T
E) none of the above
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 13 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi *10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 333 µT B) 462 µT C) 500 µT D) 600 E) zero <div style=padding-top: 35px>

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 13 cm, due to the current in this toroid, is (µ0 = 4 π\pi *10-7 N/A2)

A) 333 µT
B) 462 µT
C) 500 µT
D) 600
E) zero
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 18 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi *10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 333 µT B) 400 µT C) 500 µT D) 600 E) zero <div style=padding-top: 35px>

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 18 cm, due to the current in this toroid, is (µ0 = 4 π\pi *10-7 N/A2)

A) 333 µT
B) 400 µT
C) 500 µT
D) 600
E) zero
Question
<strong> The graph that best represents B as a function of r for a wire of radius R carrying a current I uniformly distributed over its cross-sectional area is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The graph that best represents B as a function of r for a wire of radius R carrying a current I uniformly distributed over its cross-sectional area is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field at a distance of 5.0 cm from the center of the wire is approximately</strong> A) 0.47 mT B) 1.5 mT C) 0.30 mT D) 0.56 mT E) 0.24 mT <div style=padding-top: 35px> at a distance of 5.0 cm from the center of the wire is approximately

A) 0.47 mT
B) 1.5 mT
C) 0.30 mT
D) 0.56 mT
E) 0.24 mT
Question
Ampère's law is valid

A) when there is a high degree of symmetry in the geometry of the situation.
B) when there is no symmetry.
C) when the current is constant.
D) when the magnetic field is constant.
E) for all of these conditions.
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: -A coil of radius R = 5 cm lies inside a long solenoid which carries a current I<sub>1</sub> = 10 A and has 800 turns/m. The coil carries a current I<sub>2</sub> = 4 A and the normal of the plane of the coil is at an angle \theta = 30 \degree with the axis of the solenoid. The magnetic field produced by the solenoid at the center is ____ times greater than the magnetic field by the coil at the center.</strong> A) 100 B) 200 C) 1000 D) 2000 E) 8000 <div style=padding-top: 35px>

-A coil of radius R = 5 cm lies inside a long solenoid which carries a current I1 = 10 A and has 800 turns/m. The coil carries a current I2 = 4 A and the normal of the plane of the coil is at an angle θ\theta = 30 °\degree with the axis of the solenoid. The magnetic field produced by the solenoid at the center is ____ times greater than the magnetic field by the coil at the center.

A) 100
B) 200
C) 1000
D) 2000
E) 8000
Question
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field 0.20 cm from the center of the wire is approximately</strong> A) 2.5 mT B) 8.8 \mu T C) 3.8 mT D) 15 mT E) 2.9 \mu T <div style=padding-top: 35px> 0.20 cm from the center of the wire is approximately

A) 2.5 mT
B) 8.8 μ\mu T
C) 3.8 mT
D) 15 mT
E) 2.9 μ\mu T
Question
A long solenoid of radius 3 cm has 1100 turns per m. If the solenoid wire carries a current of 1.5 A, then calculate the magnetic field inside the solenoid.

A) 2.1 * 10-3 T
B) 1.0 *10-3 T
C) 1.7 *10-4 T
D) 7.0 *10-2 T
E) none of the above
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 10 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi * 10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 400 µT B) 500 µT C) 600 µT D) zero E) impossible to calculate without additional information. <div style=padding-top: 35px>

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 10 cm, due to the current in this toroid, is (µ0 = 4 π\pi * 10-7 N/A2)

A) 400 µT
B) 500 µT
C) 600 µT
D) zero
E) impossible to calculate without additional information.
Question
The orbital magnetic moment of an atomic electron is

A) directly proportional to its angular momentum.
B) directly proportional to the electronic charge.
C) inversely proportional to the mass of the electron.
D) quantized as a consequence of the quantization of angular momentum.
E) described by all of the above.
Question
A wire of radius 0.6 cm carries a current of 10 A that is uniformly distributed over its cross section. Calculate the magnetic field strength at r = 0.3 cm divided by that at r = 0.9 cm.

A) 1.0
B) 0.75
C) 0.50
D) 2.0
E) 3.0
Question
A long straight wire of radius R carries a current density J = kr A/m2 where k is a constant. The magnetic field for r > R is (Hint: Current enclosed <strong>A long straight wire of radius R carries a current density J = kr A/m<sup>2</sup> where k is a constant. The magnetic field for r > R is (Hint: Current enclosed .)</strong> A) \mu <sub>0</sub>kR<sup>3</sup>/3r B) 2 \pi\mu <sub>0</sub>kR<sup>3</sup>/3r C) 2 \pi\mu <sub>0</sub>kR<sup>2</sup>/r D) 2 \pi\mu <sub>0</sub>kR/2 E) none of the above <div style=padding-top: 35px> .)

A) μ\mu 0kR3/3r
B) 2 π\piμ\mu 0kR3/3r
C) 2 π\piμ\mu 0kR2/r
D) 2 π\piμ\mu 0kR/2
E) none of the above
Question
Gauss's law for magnetism summarizes the fact(s) that

A) the magnetic flux through a closed surface is zero.
B) the magnetic flux is given by <strong>Gauss's law for magnetism summarizes the fact(s) that</strong> A) the magnetic flux through a closed surface is zero. B) the magnetic flux is given by <sub>S</sub>B dA. C) the existence of magnetic monopoles has yet to be verified. D) there is no point in space from which magnetic field lines diverge. E) all of the above are true. <div style=padding-top: 35px> SB dA.
C) the existence of magnetic monopoles has yet to be verified.
D) there is no point in space from which magnetic field lines diverge.
E) all of the above are true.
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Deck 7: Sources of the Magnetic Field
1
A particle with charge q = 5 μ\mu C is moving with velocity <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. . At t = 0, it is located at the origin. The magnetic field at <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct. at t = 0 is

A) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct.
B) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct.
C) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct.
D) <strong>A particle with charge q = 5 \mu C is moving with velocity . At t = 0, it is located at the origin. The magnetic field at at t = 0 is</strong> A) B) C) D) E) None of these is correct.
E) None of these is correct.

2
<strong> A positively charged body is moving in the positive x direction as shown. The direction of the magnetic field at the origin due to the motion of this charged body is</strong> A) 1 B) 2 C) 3 D) 4 E) None of these is correct, as this charged body does not create a magnetic field along the axis of its motion. A positively charged body is moving in the positive x direction as shown. The direction of the magnetic field at the origin due to the motion of this charged body is

A) 1
B) 2
C) 3
D) 4
E) None of these is correct, as this charged body does not create a magnetic field along the axis of its motion.
4
3
The magnitude of the magnetic field due to the presence of a charged body

A) varies directly with the speed of the body.
B) varies directly with the charge carried by the body.
C) varies inversely with the square of the distance between the charged body and the field point.
D) depends on the magnetic properties of the space between the charged body and the field point.
E) is described by all of these.
is described by all of these.
4
<strong> Two wires lying in the plane of this page carry equal currents in opposite directions, as shown. At a point midway between the wires, the magnetic field is</strong> A) zero. B) into the page. C) out of the page. D) toward the top or bottom of the page. E) toward one of the two wires. Two wires lying in the plane of this page carry equal currents in opposite directions, as shown. At a point midway between the wires, the magnetic field is

A) zero.
B) into the page.
C) out of the page.
D) toward the top or bottom of the page.
E) toward one of the two wires.
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5
A point charge is moving with speed 2 *107 m/s along the x axis. At t = 0, the charge is at x = 0 m and the magnitude of the magnetic field at x = 4 m is B0. The magnitude of the magnetic field at x = 4m when t = 0.1 μ\mu s is

A) B0/2
B) B0
C) B0/4
D) 2B0
E) 4B0
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6
<strong> A positively charged body is moving in the negative z direction as shown. The direction of the magnetic field due to the motion of this charged body at point P is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 A positively charged body is moving in the negative z direction as shown. The direction of the magnetic field due to the motion of this charged body at point P is

A) 1
B) 2
C) 3
D) 4
E) 5
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7
The top diagram shows the velocity of a positively charged particle. The direction of the magnetic field due to the moving charge at r is best represented by <strong>The top diagram shows the velocity of a positively charged particle. The direction of the magnetic field due to the moving charge at r is best represented by </strong> A) 1 B) 2 C) 3 D) 4 E) 5

A) 1
B) 2
C) 3
D) 4
E) 5
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8
At a certain instant of time a particle with charge q = 25 μ\mu C is located at x = 4.0 m, y = 2.0 m; its velocity at that time is v = -20 m/s <strong>At a certain instant of time a particle with charge q = 25 \mu C is located at x = 4.0 m, y = 2.0 m; its velocity at that time is v = -20 m/s . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?</strong> A) 6.8 pT B) 1.1 pT C) 5.6 pT D) 2.2 pT E) 4.4 pT . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?

A) 6.8 pT
B) 1.1 pT
C) 5.6 pT
D) 2.2 pT
E) 4.4 pT
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9
<strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT A point charge of q1 = 5.8 nC is moving with speed 2.5 * 107 m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately

A) 0.70 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT
B) -0.70 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT
C) 3.2 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT
D) -1.6 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT
E) -0.35 nT <strong> A point charge of q<sub>1</sub> = 5.8 nC is moving with speed 2.5 * 10<sup>7</sup> m/s parallel to the z axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, z = 4 m is approximately</strong> A) 0.70 nT B) -0.70 nT C) 3.2 nT D) -1.6 nT E) -0.35 nT
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10
<strong> At the instant the positively charged body is at the origin, the magnetic field at point P due to the motion of this charged body is in the negative x direction. The charged body must be moving</strong> A) in the negative z direction. B) in the positive y direction. C) in the positive x direction. D) in the negative y direction. E) in the positive z direction. At the instant the positively charged body is at the origin, the magnetic field at point P due to the motion of this charged body is in the negative x direction. The charged body must be moving

A) in the negative z direction.
B) in the positive y direction.
C) in the positive x direction.
D) in the negative y direction.
E) in the positive z direction.
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11
In a simple picture of the hydrogen atom, the electron moves in circular orbits around the central proton attracted by the Coulomb force. The lowest (n = 1) energy orbit that is allowed for the electron is at a radius of 5.29*10-11 m and the second (n = 2) lowest allowed orbit is at 4 times this radius. Calculate the magnetic field strength at the proton due to the orbital motion of the electron in the n = 2 state.

A) 0 T
B) 6.3 T
C) 0.39 T
D) 12.5 T
E) None of the above
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12
The Biot-Savart law is similar to Coulomb's law in that both

A) are inverse square laws.
B) include the permeability of free space.
C) deal with excess charges.
D) are not electrical in nature.
E) are described by none of the above.
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13
The magnetic field due to the presence of a charged body

A) depends on whether the charged body is moving.
B) depends on the direction the charged body is moving in relationship to the location of the field point.
C) varies inversely with the square of the distance between the charged body and the field point.
D) depends on the magnetic properties of the space between the charged body and the field point.
E) is described by all of these.
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14
In a simple picture of the hydrogen atom, the electron moves in circular orbits around the central proton attracted by the Coulomb force. The lowest (n = 1) energy orbit that is allowed for the electron is at a radius of 5.29 *10-11 m and the second (n = 2) lowest allowed orbit is at 4 times this radius. How many times stronger is the magnetic field strength at the proton due to the orbital motion of the electron in the n = 1 state than the n = 2 state?

A) 64
B) 16
C) 4
D) 1
E) 32
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15
<strong> At the instant the negatively charged body is at the origin, the magnetic field at point P due to its motion is in the negative x direction. The charged body must be moving</strong> A) in the negative z direction. B) in the positive y direction. C) in the positive x direction. D) in the negative y direction. E) in the positive z direction. At the instant the negatively charged body is at the origin, the magnetic field at point P due to its motion is in the negative x direction. The charged body must be moving

A) in the negative z direction.
B) in the positive y direction.
C) in the positive x direction.
D) in the negative y direction.
E) in the positive z direction.
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16
A wire carries an electric current straight upward. What is the direction of the magnetic field due to the current north of the wire?

A) north
B) east
C) west
D) south
E) upward
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17
What is the direction of the magnetic field around a wire carrying a current perpendicularly into this page?

A) The field is parallel to and in the same direction as the current flow.
B) It is parallel to but directed opposite to the current flow.
C) It is counterclockwise around the wire in the plane of the page.
D) It is clockwise around the wire in the plane of the page.
E) None of these is correct.
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18
<strong> Two positively charged bodies are moving in opposite directions on parallel paths that lie in the xz plane. Their speeds are equal and their trajectories are equidistant from the x axis. The magnetic field at the origin, due to the motion of these charged bodies will be</strong> A) in the x direction. B) in the y direction. C) in all directions. D) in the z direction. E) zero. Two positively charged bodies are moving in opposite directions on parallel paths that lie in the xz plane. Their speeds are equal and their trajectories are equidistant from the x axis. The magnetic field at the origin, due to the motion of these charged bodies will be

A) in the x direction.
B) in the y direction.
C) in all directions.
D) in the z direction.
E) zero.
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19
<strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT A point charge of q1 = 3.6 nC is moving with speed 4.5 * 107 m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately

A) 0.39 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT
B) -0.78 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT
C) -0.39 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT
D) 0.78 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT
E) 2.0 nT <strong> A point charge of q<sub>1</sub> = 3.6 nC is moving with speed 4.5 * 10<sup>7</sup> m/s parallel to the y axis along the line x = 3 m. The magnetic field produced by this charge at the origin when it is at the point x = 3 m, y = 4 m is approximately</strong> A) 0.39 nT B) -0.78 nT C) -0.39 nT D) 0.78 nT E) 2.0 nT
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20
At a certain instant of time a particle with charge q = 15 μ\mu C is located at x = 2.0 m, y = 5.0 m; its velocity at that time is v = 40 m/s <strong>At a certain instant of time a particle with charge q = 15 \mu C is located at x = 2.0 m, y = 5.0 m; its velocity at that time is v = 40 m/s . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?</strong> A) 1.9 pT B) 3.8 pT C) 2.7 pT D) 4.1 pT E) 5.9 pT . If you are at the origin, what do you measure as the magnitude of the magnetic field due to this moving point charge?

A) 1.9 pT
B) 3.8 pT
C) 2.7 pT
D) 4.1 pT
E) 5.9 pT
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21
<strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E) Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is

A) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E)
B) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E)
C) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E)
D) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E)
E) <strong> Four wires carry equal currents along the four parallel edges of a cube. A parallel current-carrying wire through the center of the cube is free to move. The vector that might represent the direction in which the center wire will move is</strong> A) B) C) D) E)
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22
The magnetic field at a distance of 50 cm from a long, straight wire carrying a current of 5.0 A is approximately

A) 10 μ\mu T
B) 50 μ\mu T
C) 5.0 μ\mu T
D) 32 μ\mu T
E) 2.0 μ\mu T
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23
<strong> The sketch shows a circular coil in the xz plane carrying a current I. The direction of the magnetic field at point O is</strong> A) x B) -x C) y D) -y E) -z The sketch shows a circular coil in the xz plane carrying a current I. The direction of the magnetic field at point O is

A) x
B) -x
C) y
D) -y
E) -z
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24
<strong> An electron beam travels counterclockwise in a circle in the magnetic field produced by the Helmholtz coils, as shown. Assuming that Earth's field is downward, one can conclude that</strong> A) the Helmholtz field equals Earth's field. B) the current in the coils moves in the same direction as the electron beam. C) the current in the coils moves in the direction opposite to the electron beam. D) the Helmholtz field curves in the direction of the electron beam. E) the Helmholtz field curves in a direction opposite to the electron beam. An electron beam travels counterclockwise in a circle in the magnetic field produced by the Helmholtz coils, as shown. Assuming that Earth's field is downward, one can conclude that

A) the Helmholtz field equals Earth's field.
B) the current in the coils moves in the same direction as the electron beam.
C) the current in the coils moves in the direction opposite to the electron beam.
D) the Helmholtz field curves in the direction of the electron beam.
E) the Helmholtz field curves in a direction opposite to the electron beam.
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25
At great axial distances x from a current-carrying loop the magnetic field varies as

A) x2
B) x-3
C) x-2
D) x3
E) x-1
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26
<strong> The current in a wire along the x axis flows in the positive x direction. If a proton, located as shown in the figure, has an initial velocity in the positive z direction, it experiences</strong> A) a force in the direction of positive x. B) a force in the direction of negative x. C) a force in the direction of positive z. D) a force in the direction of positive y. E) no force. The current in a wire along the x axis flows in the positive x direction. If a proton, located as shown in the figure, has an initial velocity in the positive z direction, it experiences

A) a force in the direction of positive x.
B) a force in the direction of negative x.
C) a force in the direction of positive z.
D) a force in the direction of positive y.
E) no force.
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27
A circular loop of wire 10 cm in radius carries a current of 20 A. The axial magnetic field 15 cm from the center of the loop is approximately

A) 37 μ\mu T
B) 13 μ\mu T
C) 21 μ\mu T
D) 41 μ\mu T
E) 18 μ\mu T
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28
<strong> A solenoid carries a current I. An electron is injected with velocity along the axis AB of the solenoid. When the electron is at C, it experiences a force that is</strong> A) zero. B) not zero and along AB. C) not zero and along BA. D) not zero and perpendicular to the page. E) None of these is correct. A solenoid carries a current I. An electron is injected with velocity <strong> A solenoid carries a current I. An electron is injected with velocity along the axis AB of the solenoid. When the electron is at C, it experiences a force that is</strong> A) zero. B) not zero and along AB. C) not zero and along BA. D) not zero and perpendicular to the page. E) None of these is correct. along the axis AB of the solenoid. When the electron is at C, it experiences a force that is

A) zero.
B) not zero and along AB.
C) not zero and along BA.
D) not zero and perpendicular to the page.
E) None of these is correct.
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29
<strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E) A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is

A) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E)
B) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E)
C) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E)
D) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E)
E) <strong> A long conductor carrying current I lies in the xz plane parallel to the z axis. The current travels in the negative z direction, as shown in the figure. The vector that represents the magnetic field at the origin O is</strong> A) B) C) D) E)
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30
When the positive current in a long wire is flowing in a direction from S to N, it creates a magnetic field below the wire that is directed

A) from E to W.
B) from N to S.
C) from NE to SW.
D) from S to N.
E) from W to E.
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31
<strong> Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( ) point in the direction of the negative x axis?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( <strong> Each of the figures shown is the source of a magnetic field. In which figure does the magnetic dipole vector ( ) point in the direction of the negative x axis?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 ) point in the direction of the negative x axis?

A) 1
B) 2
C) 3
D) 4
E) 5
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32
<strong> The graph that best represents the magnetic field B between the coils of radius R of a Helmholtz pair as a function of distance along the axis of the pair is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The graph that best represents the magnetic field B between the coils of radius R of a Helmholtz pair as a function of distance along the axis of the pair is

A) 1
B) 2
C) 3
D) 4
E) 5
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33
In a circular loop of wire lying on a horizontal floor, the current is constant and, to a person looking downward, has a clockwise direction. The accompanying magnetic field at the center of the circle is directed

A) horizontally and to the east.
B) horizontally and to the north.
C) vertically upward.
D) parallel to the floor.
E) vertically downward.
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34
<strong> An electron beam travels counterclockwise in a circle of radius R in the magnetic field produced by the Helmholtz coils as shown. If you increase the current in the Helmholtz coils, the electron beam will</strong> A) increase its radius. B) decrease its radius. C) maintain the same radius. D) reverse and travel clockwise with the same radius. E) reverse and travel clockwise with a larger radius. An electron beam travels counterclockwise in a circle of radius R in the magnetic field produced by the Helmholtz coils as shown. If you increase the current in the Helmholtz coils, the electron beam will

A) increase its radius.
B) decrease its radius.
C) maintain the same radius.
D) reverse and travel clockwise with the same radius.
E) reverse and travel clockwise with a larger radius.
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35
What is the magnetic field at the center of a circular loop with a diameter of 15.0 cm that carries a current of 1.50 A?

A) zero
B) 6.28 *10-6 T
C) 1.26 * 10-5 T
D) 2.51* 10-5 T
E) 1.68* 10-4 T
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36
A circular loop of wire of radius 6.0 cm has 30 turns and lies in the xy plane. It carries a current of 5 A in such a direction that the magnetic moment of the loop is along the x axis. The magnetic field on the x axis at x = 6.0 cm is approximately

A) 19 μ\mu T
B) 0.56 mT
C) 0.11 mT
D) 47 μ\mu T
E) 0.88 mT
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37
<strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct. Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is

A) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct.
B) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct.
C) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct.
D) <strong> Two straight wires perpendicular to the plane of this page are shown in the figure. The currents in the wires are the same. The current in M is into the page and the current in N is out of the page. The vector that represents the resultant magnetic field at point P is</strong> A) B) C) D) E) None of these is correct.
E) None of these is correct.
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38
Two current-carrying wires are perpendicular to each other. The current in one flows vertically upward and the current in the other flows horizontally toward the east. The horizontal wire is 1 m south of the vertical wire. What is the direction of the net magnetic force on the horizontal wire?

A) north
B) east
C) west
D) south
E) There is no net magnetic force on the horizontal wire.
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39
A 1000-turn solenoid is 50 cm long and has a radius of 2.0 cm. It carries a current of 8.0 A. What is the magnetic field inside the solenoid near its center?

A) 2.0 * 10-2 T
B) 3.2 * 10-3 T
C) 4.0 * 10-4 T
D) 1.0 T
E) 2.0 * 10-4 T
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40
A circular loop of wire 1.0 cm in radius carries a current of 30 A. The magnetic field at the center of the loop is

A) 1.9 mT
B) 2.4 mT
C) 3.8 mT
D) 12 μ\mu T
E) 48 μ\mu T
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41
<strong> Two very long, parallel conducting wires carry equal currents in opposite directions. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 Two very long, parallel conducting wires carry equal currents in opposite directions. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?

A) 1
B) 2
C) 3
D) 4
E) 5
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42
Two straight rods 60 cm long and 2.0 mm apart in a current balance carry currents of 18 A each in opposite directions. What mass must be placed on the upper rod to balance the magnetic force of repulsion?

A) 0.50 g
B) 0.99 g
C) 9.7 g
D) 4.3 g
E) 1.6 g
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43
<strong> Two very long, parallel conducting wires carry equal currents in the same direction, as shown. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 Two very long, parallel conducting wires carry equal currents in the same direction, as shown. The numbered diagrams show end views of the wires and the resultant force vectors due to current flow in each wire. Which diagram best represents the direction of the forces?

A) 1
B) 2
C) 3
D) 4
E) 5
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44
The force per unit length between two current-carrying wires is expressed as
F/l = ( μ\mu 0/2 π\pi d)I2
Where I is the current, d the separation of the wires, and l the length of each wire. A plot of force per unit length versus I2 gives a straight line, the slope of which is

A) μ\mu 0
B) F/l
C) (2 π\pi d/ μ\mu 0)1/2
D) μ\mu 0/2 π\pi d
E) FI2/l
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45
Two long, straight parallel wires 9.3 cm apart carry currents of equal magnitude I. They repel each other with a force per unit length of 5.8 nN/m. The current I is approximately

A) 27 mA
B) 65 mA
C) 43 mA
D) 52 mA
E) 2.7 mA
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46
<strong> Calculate the magnetic field at the center of a circular current loop of radius R divided by the magnetic field at a distance R away from a very long straight wire carrying the same current value I. (Note the loop and wire are not in electrical contact.)</strong> A) 3.14 B) 1.00 C) 2.00 D) 0.318 E) 0.500 Calculate the magnetic field at the center of a circular current loop of radius R divided by the magnetic field at a distance R away from a very long straight wire carrying the same current value I. (Note the loop and wire are not in electrical contact.)

A) 3.14
B) 1.00
C) 2.00
D) 0.318
E) 0.500
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47
Calculate the magnetic field at the center of a circular current loop of area 0.200 m2 divided by the magnetic field at the center of a square current loop of the same inside area for the same current I value.

A) 1.00
B) 1.02
C) 0.246
D) 0.985
E) 0.785
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48
If the magnetic field at the center of a square current loop of side L = 40 cm is
2)4 *10-6 T calculate the current flowing around the loop.

A) 11 A
B) 3.4 A
C) 0.85 A
D) 0.21 A
E) 1.7 A
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49
<strong> Calculate the magnetic field and its direction at point P, which is 2.0 cm away from the top wire and 4.0 cm from the bottom wire. Assume both wires are infinitely long and each carries a current of 1.5 A.</strong> A) 2.3 *10<sup>-5</sup> T directed OUT of the page B) 7.5 *10<sup>-6</sup> T directed INTO the page C) 2.3 *10<sup>-5</sup> T directed INTO the page D) 7.5 * 10<sup>-6</sup> T directed OUT of the page E) 1.1 * 10<sup>-5</sup> T directed OUT of the page Calculate the magnetic field and its direction at point P, which is 2.0 cm away from the top wire and 4.0 cm from the bottom wire. Assume both wires are infinitely long and each carries a current of 1.5 A.

A) 2.3 *10-5 T directed OUT of the page
B) 7.5 *10-6 T directed INTO the page
C) 2.3 *10-5 T directed INTO the page
D) 7.5 * 10-6 T directed OUT of the page
E) 1.1 * 10-5 T directed OUT of the page
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50
Use the following to answer the next question: <strong>Use the following to answer the next question: -Two long parallel wires are a distance d apart (d = 6 cm) and carry equal and opposite currents of 5 A. Point P is distance d from each of the wires. Calculate the magnitude of the magnetic field strength at point P.</strong> A) 2.9 * 10<sup>-5</sup> T B) 8.5*10<sup>-6</sup> T C) 3.3 *10<sup>-5</sup> T D) 1.7* 10<sup>-5</sup> T E) none of the above

-Two long parallel wires are a distance d apart (d = 6 cm) and carry equal and opposite currents of 5 A. Point P is distance d from each of the wires. Calculate the magnitude of the magnetic field strength at point P.

A) 2.9 * 10-5 T
B) 8.5*10-6 T
C) 3.3 *10-5 T
D) 1.7* 10-5 T
E) none of the above
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51
The two wires in a DC adapter cable are 5 mm apart and carry a current of 4 A. If the cable is 1.5 m long, calculate the force between the wires and state if this force is attractive or not.

A) 9.6 *10-4 N, attractive
B) 9.6 * 10-7 N, attractive
C) 1.1 * 10-8 N, attractive
D) 9.6 *10-4 N, repulsive
E) 1.1 *10-8 N, repulsive
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52
Two long, parallel wires are spaced 1 m apart in air, and you have established a current of 1 A in each. The force per unit length that each wire exerts on the other is

A) 4 μ\muπ\pi 0
B) 2 μ\muπ\pi 0
C) μ\mu 0
D) μ\mu 0/4 π\pi
E) μ\mu 0/2 π\pi
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53
Two long, straight parallel wires 7.6 cm apart carry currents of equal magnitude I. They attract each other with a force per unit length of 4.3 nN/m. The current I is approximately

A) 1.6 mA
B) 40 mA
C) 37 mA
D) 59 mA
E) 4.0 mA
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54
<strong> The graph that best represents the magnetic field on the axis inside a solenoid as a function of position x on the axis is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The graph that best represents the magnetic field on the axis inside a solenoid as a function of position x on the axis is

A) 1
B) 2
C) 3
D) 4
E) 5
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55
<strong> The magnetic field at point P, due to the current in the very long wire, varies with distance R according to</strong> A) R<sup>2 </sup> B) R<sup>-3 </sup> C) R<sup>-2 </sup> D) R<sup>3 </sup> E) R<sup>-1 </sup> The magnetic field at point P, due to the current in the very long wire, varies with distance R according to

A) R2
B) R-3
C) R-2
D) R3
E) R-1
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56
<strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E) Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is

A) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E)
B) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E)
C) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E)
D) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E)
E) <strong> Current-carrying wires are located along two edges of a cube with the directions of the currents as indicated. The vector that indicates the resultant magnetic field at the corner of the cube is</strong> A) B) C) D) E)
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57
Two straight rods 55 cm long and 1.4 mm apart in a current balance carry current I, each in opposite directions. If a mass of 1.3 g when placed on the upper rod balances the magnetic force of repulsion between the rods, then calculate the current I.

A) 160 A
B) 18 A
C) 13 A
D) 3.6 A
E) 9.0 A
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58
Two long, parallel wires are spaced 1 m apart in air, and you have established a current of 1 A in each. The force per unit length that each wire exerts on the other is approximately

A) 2 * 10-6 N/m
B) 2 * 10-5 N/m
C) 2 * 10-7 N/m
D) 2 π\pi * 10-5 N/m
E) 2 π\pi * 10-6 N/m
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59
Two parallel wires carry currents I1 and I2 = 2I1 in the same direction. Which of the following expressions shows the relationship of the forces on the wires?

A) F1 = F2
B) F1 = 2F2
C) 2F1 = F2
D) F1 = 4F2
E) 4F1 = F2
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60
Use the following to answer the next question: <strong>Use the following to answer the next question: Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? </strong> A) 1 B) 2 C) 3 D) 4 E) 5
Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? <strong>Use the following to answer the next question: Two long parallel wires are a distance d apart and carry equal and opposite currents. Point P is distance d from each of the wires. Which diagram best represents the direction of the magnetic field at point P? </strong> A) 1 B) 2 C) 3 D) 4 E) 5

A) 1
B) 2
C) 3
D) 4
E) 5
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61
<strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> If the Biot-Savart relationship d <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> = ( μ\mu 0/4 π\pi )( <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> * <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> d <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> )/r3
Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> is correctly represented by

A) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> 1
B) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> 2
C) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> 3
D) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> 4
E) <strong> If the Biot-Savart relationship d = ( \mu <sub>0</sub>/4 \pi )( * d )/r<sup>3</sup> Is used to determine the magnetic field at the point P on the axis of a circular current-carrying loop, the vector is correctly represented by</strong> A) <sub>1 </sub> B) <sub>2 </sub> C) <sub>3 </sub> D) <sub>4 </sub> E) <sub>5 </sub> 5
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62
A long straight wire of radius R carries a current density J = kr A/m2 where k is a constant. The magnetic field for r < R is (Hint: Current enclosed <strong>A long straight wire of radius R carries a current density J = kr A/m<sup>2</sup> where k is a constant. The magnetic field for r < R is (Hint: Current enclosed .)</strong> A) \mu <sub>0</sub>kr<sup>2</sup>/2 B) \mu <sub>0</sub>kr<sup>2</sup>/3 C) 2 \pi\mu <sub>0</sub>kr D) 2 \pi\mu <sub>0</sub>kr/2 E) none of the above .)

A) μ\mu 0kr2/2
B) μ\mu 0kr2/3
C) 2 π\piμ\mu 0kr
D) 2 π\piμ\mu 0kr/2
E) none of the above
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63
A coaxial cable consists of a solid inner cylindrical conductor of radius 2 mm and an outer cylindrical shell of inner radius 3 mm and outer radius 3.5 mm. A current of 15 A flows down the inner wire and an equal return current flows in the outer conductor. If we assume that the currents are uniform over the cross section of the conductors, then calculate the magnitude of the enclosed current for use in Ampere's Law at a radius of 3.25 mm.

A) 7.2 A
B) 3.8 A
C) 7.8 A
D) 11.2 A
E) 7.5 A
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64
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field at the surface of the wire is approximately</strong> A) 8.4 mT B) 4.3 mT C) 6.7 mT D) 2.3 mT E) 5.7 mT at the surface of the wire is approximately

A) 8.4 mT
B) 4.3 mT
C) 6.7 mT
D) 2.3 mT
E) 5.7 mT
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65
Use the following to answer the next question: <strong>Use the following to answer the next question: -A coil of radius R = 5 cm lies inside a long solenoid which carries a current I<sub>1</sub> = 10 A and has 800 turns/m. The coil carries a current I<sub>2</sub> = 4 A and the normal of the plane of the coil is at an angle \theta = 30 \degree with the axis of the solenoid. The magnitude of the torque on the coil is</strong> A) 1.56 * 10<sup>-4</sup> N . m B) 2.74 * 10<sup>-4</sup> N . m C) 5.03 * 10<sup>-</sup><sup>5</sup> N . m D) 3.16 * 10<sup>-4</sup> N . m E) none of the above

-A coil of radius R = 5 cm lies inside a long solenoid which carries a current I1 = 10 A and has 800 turns/m. The coil carries a current I2 = 4 A and the normal of the plane of the coil is at an angle θ\theta = 30 °\degree with the axis of the solenoid. The magnitude of the torque on the coil is

A) 1.56 * 10-4 N . m
B) 2.74 * 10-4 N . m
C) 5.03 * 10-5 N . m
D) 3.16 * 10-4 N . m
E) none of the above
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66
A wire of radius 0.6 cm carries a current of 10 A that is uniformly distributed over its cross section. Calculate the magnetic field strength at r = 0.2 cm divided by that at r = 0.4 cm.

A) 1.0
B) 0.75
C) 0.50
D) 2.0
E) 3.0
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67
A toroid has 200 turns of wire with a current of 3 A passing through the wire. The inner radius of the toroid is 3 cm and the outer radius is 5 cm. Calculate the magnetic field strength at a radius of 2 cm.

A) 6.0 * 10-3 T
B) 3.0 * 10-3 T
C) 1.2* 10-2 T
D) 4.8 F*10-4 T
E) none of the above
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68
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 13 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi *10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 333 µT B) 462 µT C) 500 µT D) 600 E) zero

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 13 cm, due to the current in this toroid, is (µ0 = 4 π\pi *10-7 N/A2)

A) 333 µT
B) 462 µT
C) 500 µT
D) 600
E) zero
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69
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 18 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi *10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 333 µT B) 400 µT C) 500 µT D) 600 E) zero

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 18 cm, due to the current in this toroid, is (µ0 = 4 π\pi *10-7 N/A2)

A) 333 µT
B) 400 µT
C) 500 µT
D) 600
E) zero
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70
<strong> The graph that best represents B as a function of r for a wire of radius R carrying a current I uniformly distributed over its cross-sectional area is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The graph that best represents B as a function of r for a wire of radius R carrying a current I uniformly distributed over its cross-sectional area is

A) 1
B) 2
C) 3
D) 4
E) 5
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71
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field at a distance of 5.0 cm from the center of the wire is approximately</strong> A) 0.47 mT B) 1.5 mT C) 0.30 mT D) 0.56 mT E) 0.24 mT at a distance of 5.0 cm from the center of the wire is approximately

A) 0.47 mT
B) 1.5 mT
C) 0.30 mT
D) 0.56 mT
E) 0.24 mT
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72
Ampère's law is valid

A) when there is a high degree of symmetry in the geometry of the situation.
B) when there is no symmetry.
C) when the current is constant.
D) when the magnetic field is constant.
E) for all of these conditions.
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73
Use the following to answer the next question: <strong>Use the following to answer the next question: -A coil of radius R = 5 cm lies inside a long solenoid which carries a current I<sub>1</sub> = 10 A and has 800 turns/m. The coil carries a current I<sub>2</sub> = 4 A and the normal of the plane of the coil is at an angle \theta = 30 \degree with the axis of the solenoid. The magnetic field produced by the solenoid at the center is ____ times greater than the magnetic field by the coil at the center.</strong> A) 100 B) 200 C) 1000 D) 2000 E) 8000

-A coil of radius R = 5 cm lies inside a long solenoid which carries a current I1 = 10 A and has 800 turns/m. The coil carries a current I2 = 4 A and the normal of the plane of the coil is at an angle θ\theta = 30 °\degree with the axis of the solenoid. The magnetic field produced by the solenoid at the center is ____ times greater than the magnetic field by the coil at the center.

A) 100
B) 200
C) 1000
D) 2000
E) 8000
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74
A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field <strong>A wire of radius 0.35 cm carries a current of 75 A that is uniformly distributed over its cross-sectional area. The magnetic field 0.20 cm from the center of the wire is approximately</strong> A) 2.5 mT B) 8.8 \mu T C) 3.8 mT D) 15 mT E) 2.9 \mu T 0.20 cm from the center of the wire is approximately

A) 2.5 mT
B) 8.8 μ\mu T
C) 3.8 mT
D) 15 mT
E) 2.9 μ\mu T
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75
A long solenoid of radius 3 cm has 1100 turns per m. If the solenoid wire carries a current of 1.5 A, then calculate the magnetic field inside the solenoid.

A) 2.1 * 10-3 T
B) 1.0 *10-3 T
C) 1.7 *10-4 T
D) 7.0 *10-2 T
E) none of the above
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76
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: -The tightly wound toroid shown consists of 100 turns of wire, each carrying a current I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 10 cm, due to the current in this toroid, is (µ<sub>0</sub> = 4 \pi * 10<sup>-7</sup> N/A<sup>2</sup>)</strong> A) 400 µT B) 500 µT C) 600 µT D) zero E) impossible to calculate without additional information.

-The tightly wound toroid shown consists of 100 turns of wire, each carrying a current
I = 3 A. If a = 12 cm and b = 15 cm, the magnetic field at r = 10 cm, due to the current in this toroid, is (µ0 = 4 π\pi * 10-7 N/A2)

A) 400 µT
B) 500 µT
C) 600 µT
D) zero
E) impossible to calculate without additional information.
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77
The orbital magnetic moment of an atomic electron is

A) directly proportional to its angular momentum.
B) directly proportional to the electronic charge.
C) inversely proportional to the mass of the electron.
D) quantized as a consequence of the quantization of angular momentum.
E) described by all of the above.
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78
A wire of radius 0.6 cm carries a current of 10 A that is uniformly distributed over its cross section. Calculate the magnetic field strength at r = 0.3 cm divided by that at r = 0.9 cm.

A) 1.0
B) 0.75
C) 0.50
D) 2.0
E) 3.0
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79
A long straight wire of radius R carries a current density J = kr A/m2 where k is a constant. The magnetic field for r > R is (Hint: Current enclosed <strong>A long straight wire of radius R carries a current density J = kr A/m<sup>2</sup> where k is a constant. The magnetic field for r > R is (Hint: Current enclosed .)</strong> A) \mu <sub>0</sub>kR<sup>3</sup>/3r B) 2 \pi\mu <sub>0</sub>kR<sup>3</sup>/3r C) 2 \pi\mu <sub>0</sub>kR<sup>2</sup>/r D) 2 \pi\mu <sub>0</sub>kR/2 E) none of the above .)

A) μ\mu 0kR3/3r
B) 2 π\piμ\mu 0kR3/3r
C) 2 π\piμ\mu 0kR2/r
D) 2 π\piμ\mu 0kR/2
E) none of the above
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80
Gauss's law for magnetism summarizes the fact(s) that

A) the magnetic flux through a closed surface is zero.
B) the magnetic flux is given by <strong>Gauss's law for magnetism summarizes the fact(s) that</strong> A) the magnetic flux through a closed surface is zero. B) the magnetic flux is given by <sub>S</sub>B dA. C) the existence of magnetic monopoles has yet to be verified. D) there is no point in space from which magnetic field lines diverge. E) all of the above are true. SB dA.
C) the existence of magnetic monopoles has yet to be verified.
D) there is no point in space from which magnetic field lines diverge.
E) all of the above are true.
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