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Deck 28: Magnetic Fields

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Question
At any point the magnetic field lines are in the direction of:

A) the magnetic force on a moving positive charge
B) the magnetic force on a moving negative charge
C) the velocity of a moving positive charge
D) the velocity of a moving negative charge
E) none of the above
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Question
A proton (charge e), traveling perpendicular to a magnetic field, experiences the same force as an alpha particle (charge 2e) which is also traveling perpendicular to the same field. The ratio of their speeds, vproton/valpha is:

A) 0.5
B) 1
C) 2
D) 4
E) 8
Question
An electron travels due north through a vacuum in a region of uniform magnetic field <strong>An electron travels due north through a vacuum in a region of uniform magnetic field that is also directed due north. It will:</strong> A) be unaffected by the field B) speed up C) slow down D) follow a right-handed corkscrew path E) follow a left-handed corkscrew path <div style=padding-top: 35px> that is also directed due north. It will:

A) be unaffected by the field
B) speed up
C) slow down
D) follow a right-handed corkscrew path
E) follow a left-handed corkscrew path
Question
At one instant an electron (charge = -1.6 *10-19C) is moving in the xy plane, the components of its velocity being vx = 5 *105 m/s and vy = 3 * 105 m/s. A magnetic field of 0.8 T is in the positive x direction. At that instant the magnitude of the magnetic force on the electron is:

A) 0
B) 2.6 * 10-14 N
C) 3.8 *10-14 N
D) 6.4 * 10-14 N
E) 1.0 *10-14 N
Question
A magnetic field exerts a force on a charged particle:

A) always
B) never
C) if the particle is moving across the field lines
D) if the particle is moving along the field lines
E) if the particle is at rest
Question
Units of a magnetic field might be:

A) C.m/s
B) C.s/m
C) C/kg
D) kg/C.s
E) N/C.m
Question
A charged particle is projected into a region of uniform, parallel, <strong>A charged particle is projected into a region of uniform, parallel, fields. The force on the particle is:</strong> A) zero B) at some angle < 90° with the field lines C) along the field lines D) perpendicular to the field lines E) unknown (need to know the sign of the charge) <div style=padding-top: 35px> fields. The force on the particle is:

A) zero
B) at some angle < 90° with the field lines
C) along the field lines
D) perpendicular to the field lines
E) unknown (need to know the sign of the charge)
Question
In the formula <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px>

A) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px>
B) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px>
C) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px>
D) all three vectors must be mutually perpendicular
E) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px> must be perpendicular to both <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both <div style=padding-top: 35px>
Question
A hydrogen atom that has lost its electron is moving east in a region where the magnetic field is directed from south to north. It will be deflected:

A) up
B) down
C) north
D) south
E) not at all
Question
An electron (charge = -1.6 *10-19C) is moving at 3 *105 m/s in the positive x direction. A magnetic field of 0.8 T is in the positive z direction. The magnetic force on the electron is:

A) 0
B) 4 * 10-14 N in the positive z direction
C) 4 *10-14 N in the negative z direction
D) 4 * 10-14 N in the positive y direction
E) 4 * 10-14 N in the negative y direction
Question
A beam of electrons is sent horizontally down the axis of a tube to strike a fluorescent screen at the end of the tube. On the way, the electrons encounter a magnetic field directed vertically downward. The spot on the screen will therefore be deflected:

A) upward
B) downward
C) to the right as seen from the electron source
D) to the left as seen from the electron source
E) not at all
Question
A uniform magnetic field is in the positive z direction. A positively charged particle is moving in the positive x direction through the field. The net force on the particle can be made zero by applying an electric field in what direction?

A) Positive y
B) Negative y
C) Positive x
D) Negative x
E) Positive z
Question
An electron is moving north in a region where the magnetic field is south. The magnetic force exerted on the electron is:

A) zero
B) up
C) down
D) east
E) west
Question
The magnetic force on a charged particle is in the direction of its velocity if:

A) it is moving in the direction of the field
B) it is moving opposite to the direction of the field
C) it is moving perpendicular to the field
D) it is moving in some other direction
E) never
Question
An electron moves in the negative x direction, through a uniform magnetic field in the negative y direction. The magnetic force on the electron is: <strong>An electron moves in the negative x direction, through a uniform magnetic field in the negative y direction. The magnetic force on the electron is: </strong> A) in the negative x direction B) in the positive y direction C) in the negative y direction D) in the positive z direction E) in the negative z direction <div style=padding-top: 35px>

A) in the negative x direction
B) in the positive y direction
C) in the negative y direction
D) in the positive z direction
E) in the negative z direction
Question
An electron is travelling in the positive x direction. A uniform electric field <strong>An electron is travelling in the positive x direction. A uniform electric field is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: </strong> A) the positive y direction B) the negative y direction C) into the page D) out of the page E) the negative x direction <div style=padding-top: 35px> is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: <strong>An electron is travelling in the positive x direction. A uniform electric field is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: </strong> A) the positive y direction B) the negative y direction C) into the page D) out of the page E) the negative x direction <div style=padding-top: 35px>

A) the positive y direction
B) the negative y direction
C) into the page
D) out of the page
E) the negative x direction
Question
A magnetic field CANNOT:

A) exert a force on a charge
B) accelerate a charge
C) change the momentum of a charge
D) change the kinetic energy of a charge
E) exist
Question
The direction of the magnetic field in a certain region of space is determined by firing a test charge into the region with its velocity in various directions in different trials. The field direction is:

A) one of the directions of the velocity when the magnetic force is zero
B) the direction of the velocity when the magnetic force is a maximum
C) the direction of the magnetic force
D) perpendicular to the velocity when the magnetic force is zero
E) none of the above
Question
An electron enters a region of uniform perpendicular <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> fields. It is observed that the velocity <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> of the electron is unaffected. A possible explanation is:

A) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> is parallel to <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> and has magnitude E/B
B) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> is parallel to <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px>
C) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> is perpendicular to both <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> and has magnitude B/E
D) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> is perpendicular to both <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible <div style=padding-top: 35px> and has magnitude E/B
E) the given situation is impossible
Question
At one instant an electron (charge = -1.6 *10-19C) is moving in the xy plane, the components of its velocity being vx = 5 *105 m/s and vy = 3 * 105 m/s. A magnetic field of 0.8 T is in the positive x direction. At that instant the magnitude of the magnetic force on the electron is:

A) 0
B) 3.8 * 10-14 N
C) 5.1 * 10-14 N
D) 6.4 *10-14 N
E) 7.5 * 10-14 N
Question
At one instant an electron is moving in the positive x direction along the x axis in a region where there is a uniform magnetic field in the positive z direction. When viewed from a point on the positive z axis, it subsequent motion is:

A) straight ahead
B) counterclockwise around a circle in the xy plane
C) clockwise around a circle in the xy plane
D) in the positive z direction
E) in the negative z direction
Question
The diagram shows a straight wire carrying a flow of electrons into the page. The wire is between the poles of a permanent magnet. The direction of the magnetic force exerted on the wire is: <strong>The diagram shows a straight wire carrying a flow of electrons into the page. The wire is between the poles of a permanent magnet. The direction of the magnetic force exerted on the wire is: </strong> A) \uparrow B) \downarrow C) \leftarrow D) \rightarrow E) into the page <div style=padding-top: 35px>

A) \uparrow
B) \downarrow
C) \leftarrow
D) \rightarrow
E) into the page
Question
The current is from left to right in the conductor shown. The magnetic field is into the page and point S is at a higher potential than point T. The charge carriers are: <strong>The current is from left to right in the conductor shown. The magnetic field is into the page and point S is at a higher potential than point T. The charge carriers are: </strong> A) positive B) negative C) neutral D) absent E) moving near the speed of light <div style=padding-top: 35px>

A) positive
B) negative
C) neutral
D) absent
E) moving near the speed of light
Question
Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these <div style=padding-top: 35px> that is perpendicular to their velocity. The radius of the resulting electron trajectory is:

A) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these <div style=padding-top: 35px>
B) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these <div style=padding-top: 35px>
C) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these <div style=padding-top: 35px>
D) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these <div style=padding-top: 35px>
E) none of these
Question
J. J. Thomson's experiment, involving the motion of an electron beam in mutually perpendicular <strong>J. J. Thomson's experiment, involving the motion of an electron beam in mutually perpendicular fields, gave the value of:</strong> A) mass of electron B) charge of electron C) Earth's magnetic field D) charge/mass ratio for electron E) Avogadro's number <div style=padding-top: 35px> fields, gave the value of:

A) mass of electron
B) charge of electron
C) Earth's magnetic field
D) charge/mass ratio for electron
E) Avogadro's number
Question
A current is clockwise around the outside edge of this page and a uniform magnetic field is directed parallel to the page, from left to right. If the magnetic force is the only force acting on the page, the page will turn so the right edge:

A) moves toward you
B) moves away from you
C) moves to your right
D) moves to your left
E) does not move
Question
The figure shows a uniform magnetic field <strong>The figure shows a uniform magnetic field directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: </strong> A) toward the top of the page B) toward the bottom of the page C) toward the left D) toward the right E) zero <div style=padding-top: 35px> directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: <strong>The figure shows a uniform magnetic field directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: </strong> A) toward the top of the page B) toward the bottom of the page C) toward the left D) toward the right E) zero <div style=padding-top: 35px>

A) toward the top of the page
B) toward the bottom of the page
C) toward the left
D) toward the right
E) zero
Question
The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page <div style=padding-top: 35px>

A) to the right
B) opposite the direction of <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page <div style=padding-top: 35px>
C) in the direction of <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page <div style=padding-top: 35px>
D) into the page
E) out of the page
Question
An electron and a proton are both initially moving with the same speed and in the same direction at 90˚ to the same uniform magnetic field. They experience magnetic forces, which are initially:

A) identical
B) equal in magnitude but opposite in direction
C) in the same direction and differing in magnitude by a factor of 1840
D) in opposite directions and differing in magnitude by a factor of 1840
E) equal in magnitude but perpendicular to each other
Question
The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines <div style=padding-top: 35px> is:

A) maximum when the plane of the loop is perpendicular to <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines <div style=padding-top: 35px>
B) maximum when the plane of the loop is parallel to <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines <div style=padding-top: 35px>
C) dependent on the shape of the loop for a fixed loop area
D) independent of the orientation of the loop
E) such as to rotate the loop around the magnetic field lines
Question
An ion with a charge of +3.25*1019 C is in region where a uniform electric field of 5 * 104. V/m is perpendicular to a uniform magnetic field of 0.8 T. If its acceleration is zero then its speed must be:

A) 0
B) 1.6 * 104 m/s
C) 4.0 * 105 m/s
D) 6.3 * 105 m/s
E) any value but 0
Question
An electron is launched with velocity <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these <div style=padding-top: 35px> in a uniform magnetic field <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these <div style=padding-top: 35px> The angle θ\theta between <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these <div style=padding-top: 35px> is between 0 and 90o. As a result, the electron follows a helix, its velocity vector <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these <div style=padding-top: 35px> returning to its initial value in a time interval of:

A) 2πm/eB
B) 2πmv/eB
C) 2πmv sin θ\theta /eB
D) 2πmv cos θ\theta /eB
E) none of these
Question
A loop of wire carrying a current of 2.0 A is in the shape of a right triangle with two equal sides, each 15 cm long. A 0.7 T uniform magnetic field is in the plane of the triangle and is perpendicular to the hypotenuse. The resultant magnetic force on the two sides has a magnitude of:

A) 0
B) 0.21 N
C) 0.30 N
D) 0.41 N
E) 0.51 N
Question
A cyclotron operates with a given magnetic field and at a given frequency. If R denotes the radius of the final orbit, the final particle energy is proportional to:

A) 1/R
B) R
C) R2
D) R3
E) R4
Question
A loop of wire carrying a current of 2.0 A is in the shape of a right triangle with two equal sides, each 15 cm long. A 0.7 T uniform magnetic field is parallel to the hypotenuse. The resultant magnetic force on the two sides has a magnitude of:

A) 0
B) 0.21 N
C) 0.30 N
D) 0.41 N
E) 0.51 N
Question
A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field <strong>A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field parallel to the side MK as indicated. The loop will tend to rotate: </strong> A) about PQ with KL coming out of the page B) about PQ with KL going into the page C) about RS with MK coming out of the page D) about RS with MK going into the page E) about an axis perpendicular to the page <div style=padding-top: 35px> parallel to the side MK as indicated. The loop will tend to rotate: <strong>A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field parallel to the side MK as indicated. The loop will tend to rotate: </strong> A) about PQ with KL coming out of the page B) about PQ with KL going into the page C) about RS with MK coming out of the page D) about RS with MK going into the page E) about an axis perpendicular to the page <div style=padding-top: 35px>

A) about PQ with KL coming out of the page
B) about PQ with KL going into the page
C) about RS with MK coming out of the page
D) about RS with MK going into the page
E) about an axis perpendicular to the page
Question
The figure shows the motion of electrons in a wire which is near the N pole of a magnet. The wire will be pushed: <strong>The figure shows the motion of electrons in a wire which is near the N pole of a magnet. The wire will be pushed: </strong> A) toward the magnet B) away from the magnet C) downwards D) upwards E) along its length <div style=padding-top: 35px>

A) toward the magnet
B) away from the magnet
C) downwards
D) upwards
E) along its length
Question
An electron and a proton both each travel with equal speeds around circular orbits in the same uniform magnetic field, as shown in the diagram (not to scale). The field is into the page on the diagram. Because the electron is less massive than the proton and because the electron is negatively charged and the proton is positively charged: <strong>An electron and a proton both each travel with equal speeds around circular orbits in the same uniform magnetic field, as shown in the diagram (not to scale). The field is into the page on the diagram. Because the electron is less massive than the proton and because the electron is negatively charged and the proton is positively charged: </strong> A) the electron travels clockwise around the smaller circle and the proton travels counterclockwise around the larger circle. B) the electron travels counterclockwise around the smaller circle and the proton travels clockwise around the larger circle C) the electron travels clockwise around the larger circle and the proton travels counterclockwise around the smaller circle D) the electron travels counterclockwise around the larger circle and the proton travels clockwise around the smaller circle E) the electron travels counterclockwise around the smaller circle and the proton travels counterclockwise around the larger circle <div style=padding-top: 35px>

A) the electron travels clockwise around the smaller circle and the proton travels counterclockwise around the larger circle.
B) the electron travels counterclockwise around the smaller circle and the proton travels clockwise around the larger circle
C) the electron travels clockwise around the larger circle and the proton travels counterclockwise around the smaller circle
D) the electron travels counterclockwise around the larger circle and the proton travels clockwise around the smaller circle
E) the electron travels counterclockwise around the smaller circle and the proton travels counterclockwise around the larger circle
Question
In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields <strong>In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields The beam then enters a region of another magnetic field perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:</strong> A) EB'/B B) EB/B' C) BB'/E D) B/EB' E) E/BB' <div style=padding-top: 35px> The beam then enters a region of another magnetic field <strong>In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields The beam then enters a region of another magnetic field perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:</strong> A) EB'/B B) EB/B' C) BB'/E D) B/EB' E) E/BB' <div style=padding-top: 35px> perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:

A) EB'/B
B) EB/B'
C) BB'/E
D) B/EB'
E) E/BB'
Question
A uniform magnetic field is directed into the page. A charged particle, moving in the plane of the page, follows a clockwise spiral of decreasing radius as shown. A reasonable explanation is: <strong>A uniform magnetic field is directed into the page. A charged particle, moving in the plane of the page, follows a clockwise spiral of decreasing radius as shown. A reasonable explanation is: </strong> A) the charge is positive and slowing down B) the charge is negative and slowing down C) the charge is positive and speeding up D) the charge is negative and speeding up E) none of the above <div style=padding-top: 35px>

A) the charge is positive and slowing down
B) the charge is negative and slowing down
C) the charge is positive and speeding up
D) the charge is negative and speeding up
E) none of the above
Question
The units of magnetic dipole moment are:

A) ampere
B) ampere .meter
C) ampere .meter2
D) ampere/meter
E) ampere/meter2
Question
The diagrms show five possible orientations of a magnetic dipole <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px> in a uniform magnetic field <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px> For which of these is the potential energy the greatest? <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px>

A) I
B) II
C) III
D) IV
E) V
Question
You are facing a loop of wire which carries a clockwise current of 3.0 A and which surrounds an area of 5.8 102m2. The magnetic dipole moment of the loop is:

A) 3.0 A . m2, into the page
B) 3.0 A . m2, out of the page
C) 0.17 A . m2, into the page
D) 0.17 A. m2, out of the page
E) 0.17 A . m2, left to right
Question
For a loop of current-carrying wire in a uniform magnetic field the potential energy is a minimum if the magnetic dipole moment of the loop is:

A) in the same direction as the field
B) in the direction opposite to that of the field
C) perpendicular to the field
D) at an angle of 45 °\degree to the field
E) none of the above
Question
A loop of current-carrying wire has a magnetic dipole moment of 5 *10-4 A .m2. The moment initially is aligned with a 0.5-T magnetic filed.To rotate the loop so its dipole momentt is perpendicular to the field and hold it in that orentation, you must do work of:

A) 0
B) 2.5 * 10-4 J
C) -2.5 * 10-4 J
D) 1.0 * 10-3 J
E) -1.0 * 10-3 J
Question
A circular loop of wire with a radius of 20 cm lies in the xy plane and carries a current of 2 A, counterclockwise when viewed from a point on the positive z axis. Its magnetic dipole moment is:

A) 0.25 A.m2, in the positive z direction
B) 0.25 A. m2, in the negative z direction
C) 2.5 A.m2, in the positive z direction
D) 2.5 A.m2, in the negative z direction
E) 0.25 A.m2, in the xy plane
Question
The magnetic dipole moment of a current-carrying loop of wire is in the positive z direction. If a uniform magnetic field is in the positive x direction the magnetic torque on the loop is:

A) 0
B) in the positive y direction
C) in the negative y direction
D) in the positive z direction
E) in the negative z direction
Question
The diagrams show five possible orientations of a magnetic dipole <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px> in a uniform magnetic field <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px> For which of these does the magnetic torque on the dipole have the greatest magnitude? <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V <div style=padding-top: 35px>

A) I
B) II
C) III
D) IV
E) V
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Deck 28: Magnetic Fields
1
At any point the magnetic field lines are in the direction of:

A) the magnetic force on a moving positive charge
B) the magnetic force on a moving negative charge
C) the velocity of a moving positive charge
D) the velocity of a moving negative charge
E) none of the above
none of the above
2
A proton (charge e), traveling perpendicular to a magnetic field, experiences the same force as an alpha particle (charge 2e) which is also traveling perpendicular to the same field. The ratio of their speeds, vproton/valpha is:

A) 0.5
B) 1
C) 2
D) 4
E) 8
2
3
An electron travels due north through a vacuum in a region of uniform magnetic field <strong>An electron travels due north through a vacuum in a region of uniform magnetic field that is also directed due north. It will:</strong> A) be unaffected by the field B) speed up C) slow down D) follow a right-handed corkscrew path E) follow a left-handed corkscrew path that is also directed due north. It will:

A) be unaffected by the field
B) speed up
C) slow down
D) follow a right-handed corkscrew path
E) follow a left-handed corkscrew path
be unaffected by the field
4
At one instant an electron (charge = -1.6 *10-19C) is moving in the xy plane, the components of its velocity being vx = 5 *105 m/s and vy = 3 * 105 m/s. A magnetic field of 0.8 T is in the positive x direction. At that instant the magnitude of the magnetic force on the electron is:

A) 0
B) 2.6 * 10-14 N
C) 3.8 *10-14 N
D) 6.4 * 10-14 N
E) 1.0 *10-14 N
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5
A magnetic field exerts a force on a charged particle:

A) always
B) never
C) if the particle is moving across the field lines
D) if the particle is moving along the field lines
E) if the particle is at rest
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6
Units of a magnetic field might be:

A) C.m/s
B) C.s/m
C) C/kg
D) kg/C.s
E) N/C.m
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7
A charged particle is projected into a region of uniform, parallel, <strong>A charged particle is projected into a region of uniform, parallel, fields. The force on the particle is:</strong> A) zero B) at some angle < 90° with the field lines C) along the field lines D) perpendicular to the field lines E) unknown (need to know the sign of the charge) fields. The force on the particle is:

A) zero
B) at some angle < 90° with the field lines
C) along the field lines
D) perpendicular to the field lines
E) unknown (need to know the sign of the charge)
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8
In the formula <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both

A) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both
B) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both
C) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both must be perpendicular to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both but not necessarily to <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both
D) all three vectors must be mutually perpendicular
E) <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both must be perpendicular to both <strong>In the formula </strong> A) must be perpendicular to but not necessarily to B) must be perpendicular to but not necessarily to C) must be perpendicular to but not necessarily to D) all three vectors must be mutually perpendicular E) must be perpendicular to both
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9
A hydrogen atom that has lost its electron is moving east in a region where the magnetic field is directed from south to north. It will be deflected:

A) up
B) down
C) north
D) south
E) not at all
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10
An electron (charge = -1.6 *10-19C) is moving at 3 *105 m/s in the positive x direction. A magnetic field of 0.8 T is in the positive z direction. The magnetic force on the electron is:

A) 0
B) 4 * 10-14 N in the positive z direction
C) 4 *10-14 N in the negative z direction
D) 4 * 10-14 N in the positive y direction
E) 4 * 10-14 N in the negative y direction
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11
A beam of electrons is sent horizontally down the axis of a tube to strike a fluorescent screen at the end of the tube. On the way, the electrons encounter a magnetic field directed vertically downward. The spot on the screen will therefore be deflected:

A) upward
B) downward
C) to the right as seen from the electron source
D) to the left as seen from the electron source
E) not at all
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12
A uniform magnetic field is in the positive z direction. A positively charged particle is moving in the positive x direction through the field. The net force on the particle can be made zero by applying an electric field in what direction?

A) Positive y
B) Negative y
C) Positive x
D) Negative x
E) Positive z
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13
An electron is moving north in a region where the magnetic field is south. The magnetic force exerted on the electron is:

A) zero
B) up
C) down
D) east
E) west
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14
The magnetic force on a charged particle is in the direction of its velocity if:

A) it is moving in the direction of the field
B) it is moving opposite to the direction of the field
C) it is moving perpendicular to the field
D) it is moving in some other direction
E) never
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15
An electron moves in the negative x direction, through a uniform magnetic field in the negative y direction. The magnetic force on the electron is: <strong>An electron moves in the negative x direction, through a uniform magnetic field in the negative y direction. The magnetic force on the electron is: </strong> A) in the negative x direction B) in the positive y direction C) in the negative y direction D) in the positive z direction E) in the negative z direction

A) in the negative x direction
B) in the positive y direction
C) in the negative y direction
D) in the positive z direction
E) in the negative z direction
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16
An electron is travelling in the positive x direction. A uniform electric field <strong>An electron is travelling in the positive x direction. A uniform electric field is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: </strong> A) the positive y direction B) the negative y direction C) into the page D) out of the page E) the negative x direction is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: <strong>An electron is travelling in the positive x direction. A uniform electric field is in the negative y direction. If a uniform magnetic field with the appropriate magnitude and direction also exists in the region, the total force on the electron will be zero. The appropriate direction for the magetic field is: </strong> A) the positive y direction B) the negative y direction C) into the page D) out of the page E) the negative x direction

A) the positive y direction
B) the negative y direction
C) into the page
D) out of the page
E) the negative x direction
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17
A magnetic field CANNOT:

A) exert a force on a charge
B) accelerate a charge
C) change the momentum of a charge
D) change the kinetic energy of a charge
E) exist
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18
The direction of the magnetic field in a certain region of space is determined by firing a test charge into the region with its velocity in various directions in different trials. The field direction is:

A) one of the directions of the velocity when the magnetic force is zero
B) the direction of the velocity when the magnetic force is a maximum
C) the direction of the magnetic force
D) perpendicular to the velocity when the magnetic force is zero
E) none of the above
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19
An electron enters a region of uniform perpendicular <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible fields. It is observed that the velocity <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible of the electron is unaffected. A possible explanation is:

A) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible is parallel to <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible and has magnitude E/B
B) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible is parallel to <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible
C) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible is perpendicular to both <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible and has magnitude B/E
D) <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible is perpendicular to both <strong>An electron enters a region of uniform perpendicular fields. It is observed that the velocity of the electron is unaffected. A possible explanation is:</strong> A) is parallel to and has magnitude E/B B) is parallel to C) is perpendicular to both and has magnitude B/E D) is perpendicular to both and has magnitude E/B E) the given situation is impossible and has magnitude E/B
E) the given situation is impossible
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20
At one instant an electron (charge = -1.6 *10-19C) is moving in the xy plane, the components of its velocity being vx = 5 *105 m/s and vy = 3 * 105 m/s. A magnetic field of 0.8 T is in the positive x direction. At that instant the magnitude of the magnetic force on the electron is:

A) 0
B) 3.8 * 10-14 N
C) 5.1 * 10-14 N
D) 6.4 *10-14 N
E) 7.5 * 10-14 N
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21
At one instant an electron is moving in the positive x direction along the x axis in a region where there is a uniform magnetic field in the positive z direction. When viewed from a point on the positive z axis, it subsequent motion is:

A) straight ahead
B) counterclockwise around a circle in the xy plane
C) clockwise around a circle in the xy plane
D) in the positive z direction
E) in the negative z direction
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22
The diagram shows a straight wire carrying a flow of electrons into the page. The wire is between the poles of a permanent magnet. The direction of the magnetic force exerted on the wire is: <strong>The diagram shows a straight wire carrying a flow of electrons into the page. The wire is between the poles of a permanent magnet. The direction of the magnetic force exerted on the wire is: </strong> A) \uparrow B) \downarrow C) \leftarrow D) \rightarrow E) into the page

A) \uparrow
B) \downarrow
C) \leftarrow
D) \rightarrow
E) into the page
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23
The current is from left to right in the conductor shown. The magnetic field is into the page and point S is at a higher potential than point T. The charge carriers are: <strong>The current is from left to right in the conductor shown. The magnetic field is into the page and point S is at a higher potential than point T. The charge carriers are: </strong> A) positive B) negative C) neutral D) absent E) moving near the speed of light

A) positive
B) negative
C) neutral
D) absent
E) moving near the speed of light
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24
Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these that is perpendicular to their velocity. The radius of the resulting electron trajectory is:

A) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these
B) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these
C) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these
D) <strong>Electrons (mass m, charge -e) are accelerated from rest through a potential difference V and are then deflected by a magnetic field that is perpendicular to their velocity. The radius of the resulting electron trajectory is:</strong> A) B) C) D) E) none of these
E) none of these
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25
J. J. Thomson's experiment, involving the motion of an electron beam in mutually perpendicular <strong>J. J. Thomson's experiment, involving the motion of an electron beam in mutually perpendicular fields, gave the value of:</strong> A) mass of electron B) charge of electron C) Earth's magnetic field D) charge/mass ratio for electron E) Avogadro's number fields, gave the value of:

A) mass of electron
B) charge of electron
C) Earth's magnetic field
D) charge/mass ratio for electron
E) Avogadro's number
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26
A current is clockwise around the outside edge of this page and a uniform magnetic field is directed parallel to the page, from left to right. If the magnetic force is the only force acting on the page, the page will turn so the right edge:

A) moves toward you
B) moves away from you
C) moves to your right
D) moves to your left
E) does not move
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27
The figure shows a uniform magnetic field <strong>The figure shows a uniform magnetic field directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: </strong> A) toward the top of the page B) toward the bottom of the page C) toward the left D) toward the right E) zero directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: <strong>The figure shows a uniform magnetic field directed to the left and a wire carrying a current into the page. The magnetic force acting on the wire is: </strong> A) toward the top of the page B) toward the bottom of the page C) toward the left D) toward the right E) zero

A) toward the top of the page
B) toward the bottom of the page
C) toward the left
D) toward the right
E) zero
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28
The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page

A) to the right
B) opposite the direction of <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page
C) in the direction of <strong>The diagram shows a straight wire carrying current i in a uniform magnetic field. The magnetic force on the wire is indicated by an arrow but the magnetic field is not shown. Of the following possibilities, the direction of the magnetic field is: </strong> A) to the right B) opposite the direction of C) in the direction of D) into the page E) out of the page
D) into the page
E) out of the page
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29
An electron and a proton are both initially moving with the same speed and in the same direction at 90˚ to the same uniform magnetic field. They experience magnetic forces, which are initially:

A) identical
B) equal in magnitude but opposite in direction
C) in the same direction and differing in magnitude by a factor of 1840
D) in opposite directions and differing in magnitude by a factor of 1840
E) equal in magnitude but perpendicular to each other
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30
The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines is:

A) maximum when the plane of the loop is perpendicular to <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines
B) maximum when the plane of the loop is parallel to <strong>The magnetic torque exerted on a flat current-carrying loop of wire by a uniform magnetic field is:</strong> A) maximum when the plane of the loop is perpendicular to B) maximum when the plane of the loop is parallel to C) dependent on the shape of the loop for a fixed loop area D) independent of the orientation of the loop E) such as to rotate the loop around the magnetic field lines
C) dependent on the shape of the loop for a fixed loop area
D) independent of the orientation of the loop
E) such as to rotate the loop around the magnetic field lines
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31
An ion with a charge of +3.25*1019 C is in region where a uniform electric field of 5 * 104. V/m is perpendicular to a uniform magnetic field of 0.8 T. If its acceleration is zero then its speed must be:

A) 0
B) 1.6 * 104 m/s
C) 4.0 * 105 m/s
D) 6.3 * 105 m/s
E) any value but 0
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32
An electron is launched with velocity <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these in a uniform magnetic field <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these The angle θ\theta between <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these is between 0 and 90o. As a result, the electron follows a helix, its velocity vector <strong>An electron is launched with velocity in a uniform magnetic field The angle \theta between is between 0 and 90<sup>o</sup>. As a result, the electron follows a helix, its velocity vector returning to its initial value in a time interval of:</strong> A) 2πm/eB B) 2πmv/eB C) 2πmv sin \theta /eB D) 2πmv cos \theta /eB E) none of these returning to its initial value in a time interval of:

A) 2πm/eB
B) 2πmv/eB
C) 2πmv sin θ\theta /eB
D) 2πmv cos θ\theta /eB
E) none of these
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33
A loop of wire carrying a current of 2.0 A is in the shape of a right triangle with two equal sides, each 15 cm long. A 0.7 T uniform magnetic field is in the plane of the triangle and is perpendicular to the hypotenuse. The resultant magnetic force on the two sides has a magnitude of:

A) 0
B) 0.21 N
C) 0.30 N
D) 0.41 N
E) 0.51 N
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34
A cyclotron operates with a given magnetic field and at a given frequency. If R denotes the radius of the final orbit, the final particle energy is proportional to:

A) 1/R
B) R
C) R2
D) R3
E) R4
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35
A loop of wire carrying a current of 2.0 A is in the shape of a right triangle with two equal sides, each 15 cm long. A 0.7 T uniform magnetic field is parallel to the hypotenuse. The resultant magnetic force on the two sides has a magnitude of:

A) 0
B) 0.21 N
C) 0.30 N
D) 0.41 N
E) 0.51 N
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36
A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field <strong>A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field parallel to the side MK as indicated. The loop will tend to rotate: </strong> A) about PQ with KL coming out of the page B) about PQ with KL going into the page C) about RS with MK coming out of the page D) about RS with MK going into the page E) about an axis perpendicular to the page parallel to the side MK as indicated. The loop will tend to rotate: <strong>A square loop of wire lies in the plane of the page and carries a current I as shown. There is a uniform magnetic field parallel to the side MK as indicated. The loop will tend to rotate: </strong> A) about PQ with KL coming out of the page B) about PQ with KL going into the page C) about RS with MK coming out of the page D) about RS with MK going into the page E) about an axis perpendicular to the page

A) about PQ with KL coming out of the page
B) about PQ with KL going into the page
C) about RS with MK coming out of the page
D) about RS with MK going into the page
E) about an axis perpendicular to the page
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37
The figure shows the motion of electrons in a wire which is near the N pole of a magnet. The wire will be pushed: <strong>The figure shows the motion of electrons in a wire which is near the N pole of a magnet. The wire will be pushed: </strong> A) toward the magnet B) away from the magnet C) downwards D) upwards E) along its length

A) toward the magnet
B) away from the magnet
C) downwards
D) upwards
E) along its length
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38
An electron and a proton both each travel with equal speeds around circular orbits in the same uniform magnetic field, as shown in the diagram (not to scale). The field is into the page on the diagram. Because the electron is less massive than the proton and because the electron is negatively charged and the proton is positively charged: <strong>An electron and a proton both each travel with equal speeds around circular orbits in the same uniform magnetic field, as shown in the diagram (not to scale). The field is into the page on the diagram. Because the electron is less massive than the proton and because the electron is negatively charged and the proton is positively charged: </strong> A) the electron travels clockwise around the smaller circle and the proton travels counterclockwise around the larger circle. B) the electron travels counterclockwise around the smaller circle and the proton travels clockwise around the larger circle C) the electron travels clockwise around the larger circle and the proton travels counterclockwise around the smaller circle D) the electron travels counterclockwise around the larger circle and the proton travels clockwise around the smaller circle E) the electron travels counterclockwise around the smaller circle and the proton travels counterclockwise around the larger circle

A) the electron travels clockwise around the smaller circle and the proton travels counterclockwise around the larger circle.
B) the electron travels counterclockwise around the smaller circle and the proton travels clockwise around the larger circle
C) the electron travels clockwise around the larger circle and the proton travels counterclockwise around the smaller circle
D) the electron travels counterclockwise around the larger circle and the proton travels clockwise around the smaller circle
E) the electron travels counterclockwise around the smaller circle and the proton travels counterclockwise around the larger circle
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39
In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields <strong>In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields The beam then enters a region of another magnetic field perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:</strong> A) EB'/B B) EB/B' C) BB'/E D) B/EB' E) E/BB' The beam then enters a region of another magnetic field <strong>In a certain mass spectrograph, an ion beam passes through a velocity filter consisting of mutually perpendicular fields The beam then enters a region of another magnetic field perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:</strong> A) EB'/B B) EB/B' C) BB'/E D) B/EB' E) E/BB' perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to:

A) EB'/B
B) EB/B'
C) BB'/E
D) B/EB'
E) E/BB'
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40
A uniform magnetic field is directed into the page. A charged particle, moving in the plane of the page, follows a clockwise spiral of decreasing radius as shown. A reasonable explanation is: <strong>A uniform magnetic field is directed into the page. A charged particle, moving in the plane of the page, follows a clockwise spiral of decreasing radius as shown. A reasonable explanation is: </strong> A) the charge is positive and slowing down B) the charge is negative and slowing down C) the charge is positive and speeding up D) the charge is negative and speeding up E) none of the above

A) the charge is positive and slowing down
B) the charge is negative and slowing down
C) the charge is positive and speeding up
D) the charge is negative and speeding up
E) none of the above
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41
The units of magnetic dipole moment are:

A) ampere
B) ampere .meter
C) ampere .meter2
D) ampere/meter
E) ampere/meter2
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42
The diagrms show five possible orientations of a magnetic dipole <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V in a uniform magnetic field <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V For which of these is the potential energy the greatest? <strong>The diagrms show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these is the potential energy the greatest? </strong> A) I B) II C) III D) IV E) V

A) I
B) II
C) III
D) IV
E) V
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43
You are facing a loop of wire which carries a clockwise current of 3.0 A and which surrounds an area of 5.8 102m2. The magnetic dipole moment of the loop is:

A) 3.0 A . m2, into the page
B) 3.0 A . m2, out of the page
C) 0.17 A . m2, into the page
D) 0.17 A. m2, out of the page
E) 0.17 A . m2, left to right
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44
For a loop of current-carrying wire in a uniform magnetic field the potential energy is a minimum if the magnetic dipole moment of the loop is:

A) in the same direction as the field
B) in the direction opposite to that of the field
C) perpendicular to the field
D) at an angle of 45 °\degree to the field
E) none of the above
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45
A loop of current-carrying wire has a magnetic dipole moment of 5 *10-4 A .m2. The moment initially is aligned with a 0.5-T magnetic filed.To rotate the loop so its dipole momentt is perpendicular to the field and hold it in that orentation, you must do work of:

A) 0
B) 2.5 * 10-4 J
C) -2.5 * 10-4 J
D) 1.0 * 10-3 J
E) -1.0 * 10-3 J
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46
A circular loop of wire with a radius of 20 cm lies in the xy plane and carries a current of 2 A, counterclockwise when viewed from a point on the positive z axis. Its magnetic dipole moment is:

A) 0.25 A.m2, in the positive z direction
B) 0.25 A. m2, in the negative z direction
C) 2.5 A.m2, in the positive z direction
D) 2.5 A.m2, in the negative z direction
E) 0.25 A.m2, in the xy plane
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47
The magnetic dipole moment of a current-carrying loop of wire is in the positive z direction. If a uniform magnetic field is in the positive x direction the magnetic torque on the loop is:

A) 0
B) in the positive y direction
C) in the negative y direction
D) in the positive z direction
E) in the negative z direction
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48
The diagrams show five possible orientations of a magnetic dipole <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V in a uniform magnetic field <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V For which of these does the magnetic torque on the dipole have the greatest magnitude? <strong>The diagrams show five possible orientations of a magnetic dipole in a uniform magnetic field For which of these does the magnetic torque on the dipole have the greatest magnitude? </strong> A) I B) II C) III D) IV E) V

A) I
B) II
C) III
D) IV
E) V
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