Question 1

A particle with a charge of 1.60 $\times$ 10^-19 and a mass of 1.67 $\times$ 10^-27 kg is found moving in a uniform magnetic field of a strength 1.50 T. The trajectory of the particle is perpendicular to the magnetic field and is circular with a radius of 1.80 cm. The velocity of the particle is

A) 2.6

\times

10⁶ m/s.
B) 2.6

\times

10³ m/s.
C) 2.6

\times

10⁴ m/s.
D) greater than 4.0

\times

10⁶m/s.

Accepted Answer

The correct answer is A because the velocity of the particle can be calculated using the formula v = qBr/m, where q is the charge of the particle, B is the strength of the magnetic field, r is the radius of the circular trajectory, and m is the mass of the particle. Plugging in the given values, we get v = (1.60 $\times$ 10^-19 C)(1.50 T)(1.80 $\times$ 10^-2 m)/(1.67 $\times$ 10^-27 kg) = 2.6 $\times$ 10⁶ m/s.

Question 2

A particle with a charge of 1.60 $\times$ 10^-19 and a mass of 1.67 $\times$ 10^-27 kg is found moving in a uniform magnetic field of a strength 1.50 T. The trajectory of the particle is perpendicular to the magnetic field and is circular with a radius of 1.80 cm. The kinetic energy of the particle is

A) 13.7 keV.
B) 27.5 keV.
C) 35.0 keV.
D) 45.5 keV.

Accepted Answer

The kinetic energy (KE) of a charged particle moving in a magnetic field can be calculated using the formula for the centripetal force required for circular motion, $F = \frac{mv^2}{r}$, where $m$ is the mass of the particle, $v$ is its velocity, and $r$ is the radius of the circular path. This force is provided by the magnetic force on a moving charge, which is $F = qvB$, where $q$ is the charge of the particle and $B$ is the magnetic field strength. Setting these two expressions for force equal to each other gives $\frac{mv^2}{r} = qvB$. Solving for $v$ gives $v = \frac{qBr}{m}$. The kinetic energy can then be calculated using $KE = \frac{1}{2}mv^2$. Substituting the expression for $v$ into the kinetic energy formula gives $KE = \frac{1}{2}m\left(\frac{qBr}{m}\right)^2 = \frac{q^2B^2r^2}{2m}$. Substituting the given values ($q = 1.60 \times 10^{-19} C$, $B = 1.50 T$, $r = 1.80 \times 10^{-2} m$, and $m = 1.67 \times 10^{-27} kg$) into this formula and converting the result to keV (1 eV = $1.60 \times 10^{-19} J$) gives a kinetic energy of approximately 27.5 keV.

Question 3

A particle with a charge of 1.60 $\times$ 10^-19 and a mass of 1.67 $\times$ 10^-27 kg is found moving in a uniform magnetic field of a strength 1.50 T. The trajectory of the particle is perpendicular to the magnetic field and is circular with a radius of 1.80 cm. The cyclotron frequency is

A) 14 MHz.
B) 23 MHz.
C) 27 MHz.
D) 27 Hz.

Accepted Answer

23 MHz.&#10;

Question 4

The cyclotron frequency depends on the following parameters except&#10;A) charge.&#10;B) magnetic field.&#10;C) mass.&#10;D) velocity.&#10;E) Hold on; the cyclotron frequency depends on all of the above parameters.

Accepted Answer

The cyclotron frequency, also known as the gyrofrequency, depends on the charge and mass of the particle and the strength of the magnetic field. It does not depend on the velocity of the particle.

Question 5

Two electrons are moving in a uniform magnetic field. The velocity of the first electron is twice the velocity of the second electron. The electron that has the longer period of motion around the cyclotron is

A) the first electron.
B) the second electron.
C) Both trajectories have the same period.
D) The paths of these electrons are not circular.

Accepted Answer

The radius of the circular path of a charged particle moving in a magnetic field is directly proportional to its velocity. Since the first electron has twice the velocity of the second, its circular path will have a larger radius.

Question 6

Two electrons are moving in a uniform magnetic field. The velocity of the first electron is twice the velocity of the second electron. The electron that has the longer period of motion around the cyclotron is

A) the first electron.
B) the second electron.
C) Both trajectories have the same period.
D) The paths of these electrons are not circular.

Accepted Answer

The period of motion for an electron in a magnetic field is independent of its velocity. It is determined by the mass of the electron and the strength of the magnetic field, both of which are constants in this scenario. Therefore, both electrons will have the same period of motion.

Question 7

The current in a wire is directed along the x axis in a uniform magnetic field that is directed along the negative x axis. The force on the wire is along the&#10;A) x axis.&#10;B) -y axis.&#10;C) z axis.&#10;D) There is no force on the wire.

Accepted Answer

The force on a current-carrying wire in a magnetic field is given by the cross product of the current direction and the magnetic field direction. When both are parallel or antiparallel, as in this case, the cross product is zero, meaning there is no force on the wire.

Question 8

A 25-cm length of wire that is carrying a current of 4.0 A is parallel to a uniform magnetic field of 2.5 T. The force on the wire is&#10;A) 2.5 N.&#10;B) 0.40 N.&#10;C) 5.0 N.&#10;D) zero.

Accepted Answer

The force on a current-carrying wire in a magnetic field is given by F = I * L * B * sin(θ). Since the wire is parallel to the magnetic field, θ = 0 degrees, and sin(0) = 0, the force is zero.

Question 9

The current in a wire is directed along the y axis in a uniform magnetic field that is directed along the negative x axis. The force on the wire is along the&#10;A) z axis.&#10;B) -z axis.&#10;C) +x axis.&#10;D) Hold on. There is no force on the wire.

Accepted Answer

The direction of the force on a current-carrying wire in a magnetic field can be determined using the right-hand rule. Point your fingers in the direction of the current (y-axis), and curl them towards the direction of the magnetic field (negative x-axis). Your thumb will point in the direction of the force, which is the positive z-axis.

Question 10

The current in a wire is directed along the y axis in a uniform magnetic field. The resulting force on the wire is directed along the negative x axis. The magnetic field is directed along the&#10;A) z axis.&#10;B) -z axis.&#10;C) +x axis.&#10;D) -y axis.

Accepted Answer

The direction of the force on a current-carrying wire in a magnetic field is given by the right-hand rule. If the current is along the y-axis and the force is along the negative x-axis, the magnetic field must be directed along the -z axis for the right-hand rule to apply.

Question 11

A 20.0-cm length of wire is aligned along the x axis and carries 5.0 mA of current. The wire is in a region where the uniform magnetic field is given by 1.5(i + 3j + 4k) mT. The net force on the wire is

A) 1.5

\mu

N.
B) 3.0

\mu

N.
C) 4.5

\mu

N.
D) 7.5

\mu

N.

Accepted Answer

The answer of A 20.0-cm length of wire is aligned...

Question 12

A 20.0-cm length of wire is aligned along the x axis and carries 5.0 mA of current. The wire is in a region where the uniform magnetic field is given by 1.5(i + 3j + 4k) mT. The net force on the wire is

A) 1.5

\mu

N.
B) 3.0

\mu

N.
C) 4.5

\mu

N.
D) 7.5

\mu

N.

Accepted Answer

The answer of A 20.0-cm length of wire is aligned...

Question 13

A wire carries 5.00 mA of current in a region where the uniform magnetic field strength is 1.50 mT. If the angle between the wire and the magnetic field is 30°, the net force per unit length on the wire is

A) zero.
B) 3.75

\mu

N/m.
C) 6.50

\mu

N/m.
D) 7.50

\mu

N/m.

Accepted Answer

The answer of A wire carries 5.00 mA of current...

Question 14

A wire carries 5.00 mA of current in a region where the uniform magnetic field strength is 1.50 mT. If the angle between the wire and the magnetic field is 30°, the net force per unit length on the wire is

A) zero.
B) 3.75

\mu

N/m.
C) 6.50

\mu

N/m.
D) 7.50

\mu

N/m.

Accepted Answer

The answer of A wire carries 5.00 mA of current...

Question 15

Two parallel wires separated by 1.5 cm both carry 1.5 A of current. The magnitude of the force per unit length on one of the wires is&#10;A) 7.5 $\mu$ N/m.&#10;B) 15 $\mu$ N/m.&#10;C) 20$\mu$ N/m.&#10;D) 30. $\mu$ N/m.

Accepted Answer

The answer of Two parallel wires separated by 1.5 cm...

Question 16

A force per unit length of 48 $\mu$ N/m is produced when two wires separated by 1.5 mm both carry the same current. The current the wires carry is&#10;A) 0.36 A.&#10;B) 0.60 A.&#10;C) 0.77 A.&#10;D) 1.0 A.

Accepted Answer

The answer of A force per unit length of 48...

Question 17

The force produced by two parallel wires with currents running in the same direction will be&#10;A) attractive.&#10;B) repulsive.&#10;C) along the axis of symmetry.&#10;D) zero.

Accepted Answer

The answer of The force produced by two parallel wires...

Question 18

A repulsive force is produced between two parallel wires. The relative directions of the currents in the wires&#10;A) are in the same direction.&#10;B) are in the opposite direction.&#10;C) cannot be determined from the information given.&#10;D) depend on the charge carriers in the wires.

Accepted Answer

The answer of A repulsive force is produced between two...

Question 19

Two current-carrying wires produce a repulsive force of magnitude F₀. The current in each wire is doubled, resulting in a force whose magnitude is A) (1/2)F₀. B) F₀. C) 2F₀. D) 4F₀.

Accepted Answer

The answer of Two current-carrying wires produce a repulsive force...

Question 20

Two current-carrying wires produce a repulsive force of magnitude F₀ when the wires are separated by a distance of r₀. The distance between the two wires is changed to 2r₀, resulting in a force whose magnitude is

A) (1/2)F₀.
B) F₀.
C) 2F₀.
D) 4F₀.

Accepted Answer

The answer of Two current-carrying wires produce a repulsive force...

Question 21

Two current-carrying wires produce a repulsive force of magnitude F₀ when the wires are separated by a distance of r₀. If the current is doubled in each wire while the distance between the two wires is changed to 2r₀, a force results with a magnitude of

A) (1/2)F₀.
B) F₀.
C) 2F₀.
D) 4F₀.

Accepted Answer

The answer of Two current-carrying wires produce a repulsive force...

Question 22

The SI unit associate with the magnetic moment$\mu$, is A) ampere·m². B) ampere/m². C) ampere²·m. D) ampere²/m².

Accepted Answer

The answer of The SI unit associate with the magnetic...

Question 23

A loop of wire has an area of 0.10 m² and carries 15 mA of current. The magnetic moment of the loop is A) 0.001 A·m². B) 0.15 A/m². C) 71 *10^-5 A²/m. D) 2.25 A²/m².

Accepted Answer

The answer of A loop of wire has an area...

Question 24

The maximum torque of a 100-turn loop of wire that has an area of 0.15 m² and is carrying 1.5 A of current in a uniform magnetic field of 2.0 T is A) zero. B) 5.0 N·m. C) 15 N·m. D) 45 N·m.

Accepted Answer

The answer of The maximum torque of a 100-turn loop...

Question 25

A 100-turn loop of wire whose area is 0.15 m² carries 3.0 A of current. If a uniform magnetic field of 2.0 T makes an angle of 60° with the plane of the loop, the maximum torque on the loop is A) zero. B) 5.0 N·m. C) 15 N·m. D) 45 N·m.

Accepted Answer

The answer of A 100-turn loop of wire whose area...

Question 26

A rectangular loop of wire whose dimensions are 15 cm * 25 cm carries a current of 5.0 A. The loop is in a uniform magnetic field of 1.5 T whose direction is perpendicular to the plane of the loop. The torque acting on the loop is

A) zero.
B) 0.24 N·m.
C) 0.28 N·m.
D) 0.35 N·m.

Accepted Answer

The answer of A rectangular loop of wire whose dimensions...

Question 27

A rectangular loop of wire whose dimensions are 15 cm * 25 cm carries a current of 5.0 A. The loop is in a uniform magnetic field of 1.5 T whose direction is perpendicular to the plane of the loop. The torque acting on the loop is

A) zero.
B) 0.24 N·m.
C) 0.28 N·m.
D) 0.35 N·m.

Accepted Answer

The answer of A rectangular loop of wire whose dimensions...

Question 28

The magnitude of the torque produced by a magnetic moment $\mu$ = 2.0 (2i + j) A·m² in a magnetic field given by 1.5 (i + 4k) mT is A) zero. B) 3 mN·m. C) 9 mN·m. D) 27 mN·m.

Accepted Answer

The answer of The magnitude of the torque produced by...

Question 29

The magnitude of the torque produced by a magnetic moment $\mu$ = 2.0 (2i + j) A·m² in a magnetic field given by 1.5 (i + k) mT is A) 3.0 (i - 2j - 2k) mN·m. B) 9.0 mN·m. C) 3(-i + 2j - 2k) mN·m. D) zero.

Accepted Answer

The answer of The magnitude of the torque produced by...

Question 30

The potential energy of a magnetic moment $\mu$ = 1.0 (2i + j) A·m² in a magnetic field given by 1.5 (2i + k) mT is A) -6.0 mJ. B) -3.0 mJ. C) 3.0 mJ. D) -1.5 mJ.

Accepted Answer

The answer of The potential energy of a magnetic moment...

Question 31

The potential energy of a magnetic moment $\mu$ = 1.0 (-2i + j + k) A·m² in a magnetic field given by 1.5 (i + j + k)mT is A) zero. B) -3.0 mJ. C) 3.0 mJ. D) -1.5 mJ.

Accepted Answer

The answer of The potential energy of a magnetic moment...

Question 32

The maximum energy difference between the parallel and antiparallel configurations produced by a magnetic moment whose magnitude is $\mu$ = 2.0 A·m² in a magnetic field given by 1.5 mT is A) zero. B) 1.5 mJ. C) 3.0 mJ. D) 6.0 mJ.

Accepted Answer

The answer of The maximum energy difference between the parallel...

Question 33

The SI units associated with magnetic susceptibility are A) A/m². B) T/m². C) T·m. D) Hold on; the magnetic susceptibility is dimensionless.

Accepted Answer

The answer of The SI units associated with magnetic susceptibility...

Question 34

Materials with a small positive magnetic susceptibility are called&#10;A) paramagnets.&#10;B) diamagnets.&#10;C) ferromagnets.&#10;D) permanent magnets.

Accepted Answer

The answer of Materials with a small positive magnetic susceptibility...

Question 35

Materials with a small negative magnetic susceptibility are called&#10;A) paramagnets.&#10;B) diamagnets.&#10;C) ferromagnets.&#10;D) permanent magnets.

Accepted Answer

The answer of Materials with a small negative magnetic susceptibility...

Question 36

The SI units associated with magnetic permeability are A) N·s/C. B) N·s²/C. C) N·s²/C². D) Hold on; the magnetic permeability is dimensionless.

Accepted Answer

The answer of The SI units associated with magnetic permeability...

Question 37

For a magnetic material the ratio of the magnetic permeability to the permeability of free space is 3. The ratio of the B_matter/B_external for this material is A) zero. B) 2 C) 3 D) 4

Accepted Answer

The answer of For a magnetic material the ratio of...

Question 38

For a magnetic material the ratio of the magnetic permeability to the permeability of free space is 11. The material is placed in a uniform magnetic field of strength 1.0 mT. The magnetic field produced in the material is approximately

A) 11 mT.
B) 10 mT.
C) 1.2 mT.
D) 1.0 mT.

Accepted Answer

The answer of For a magnetic material the ratio of...

Question 39

A Hall voltage is measured across the width of two rods under the same experimental conditions. The only variation is that the thickness of the second rod is twice that of the first rod. The Hall voltage across the second rod will be

A) twice the value measured across the first rod.
B) half of the value measured across the first rod.
C) one-quarter the value measured across the first rod.
D) Hold on; the value of the voltage will not change.

Accepted Answer

The answer of A Hall voltage is measured across the...

Question 40

A Hall voltage is measured across the width of two rods under the same experimental conditions. The only variation is that the thickness of the second rod is twice that of the first rod. The Hall voltage across the second rod will be

A) twice the value measured across the first rod.
B) half of the value measured across the first rod.
C) one-quarter the value measured across the first rod.
D) Hold on; the value of the voltage will not change.

Accepted Answer

The answer of A Hall voltage is measured across the...

Question 41

A Hall voltage is measured to be 15 $\mu$ V across the 3.0-mm dimension of a slab of copper whose overall dimensions are 2.0 * 3.0 *25.4 mm. The current passing through the copper is 20.0 A, while the magnetic field is 0.010 T. The density of the charge carriers in the material is

A) 3.3 *10²⁴ m^-3.
B) 2.8 *10²⁵ m^-3.
C) 4.2* 10²⁵ m^-3.

Accepted Answer

The answer of A Hall voltage is measured to be...

Question 42

A Hall voltage of 15 $\mu$ V is measured across a 4.0-mm side of a metal slab immersed in a magnetic field whose strength is 0.150 T. The average velocity of the charges is&#10;A) 2.5 cm/s.&#10;B) 5.0 cm/s.&#10;C) 7.5 cm/s.&#10;D) The value cannot be obtained from the information given.

Accepted Answer

The answer of A Hall voltage of 15 $\mu$ V...

Question 43

A charged particle is moving in a region where the magnetic field strength is 1.0 T directed in the +x direction and the electric field is 1500 V/m in the +y direction. The particle velocity required for a straight-line trajectory is

A) 15 km/s.
B) 2500 m/s.
C) 1500 m/s.
D) No velocity will produce a straight-line trajectory.

Accepted Answer

The answer of A charged particle is moving in a...

Question 44

A charged particle (q = 1.6 *10^-19C) enters a mass spectrometer with a speed of 2.5 * 10⁶ m/s. The magnetic field in the spectrometer, 0.25 T, produces a circular motion of the charged particle of radius 2.5 cm. The mass of the charged particle is

A) 1.0* 10^-28 kg.
B) 2.0 *10^-28 kg.
C) 3.0 * 10^-28 kg.
D) 4.0 * 10^-28 kg.

Accepted Answer

The answer of A charged particle (q = 1.6 *10^-19...

Question 45

An electron is accelerated to an energy of 100 eV and then enters a magnetic field of strength 0.15 T. The resulting radius of the electron's trajectory is A) 2.2 * 10^-4 m. B) 3.3 *10^-4 m. C) 4.4 * 10^-4 m. D) 5.5 * 10^-4 m.

Accepted Answer

The answer of An electron is accelerated to an energy...

Question 46

The energy of an electron is 100eV when it enters an E * B velocity selector that utilizes a cross electric and magnetic field to produce a zero net force on the particle. The magnitude of the magnetic field is 0.085T. The magnitude of the electric field required to produce a straight-line trajectory is

A) 5.0 *10⁴ V/m.
B) 2.5 * 10⁵ V/m.
C) 5.0 * 10⁵ V/m.
D) 2.5 * 10⁶ V/m.

Accepted Answer

The answer of The energy of an electron is 100eV...

Question 47

An electron travels in the +x direction with a velocity of 1.5 *10⁶ m/s. It enters an E * B velocity selector that utilizes a cross electric and magnetic field to produce a zero net force on the particle. The magnitude of the magnetic field is 0.10 T in the +y direction. The magnitude of the electric field required to produce a straight-line trajectory is

A) 1.5 * 10⁵ V/m in the +z direction.
B) 1.5 *0⁵ V/m in the -z direction.
C) 1.5 * 10⁵ V/m in the +y direction.
D) 1.5 * 10⁵ V/m in the -y direction.

Accepted Answer

The answer of An electron travels in the +x direction...

Question 48

The charge carriers in a metal are typically negative. A positive charge carrier&#10;A) will not change the sign of the Hall potential.&#10;B) will change the sign of the Hall potential.&#10;C) will have a zero Hall potential.&#10;D) will produce a Hall effect across the other face of the metal.

Accepted Answer

The answer of The charge carriers in a metal are...

Question 49

One side of a square loop (dimensions of 15 cm *15 cm) runs parallel to a current-carrying wire I_w = 5.0 A. The distance between the side of the loop and the wire is 5.0 cm, and 3.0 A runs through the loop. The net force on the loop is A) 1.5 $\mu$N. B) 6.8 $\mu$N. C) 13 $\mu$N. D) 20 $\mu$N.

Accepted Answer

The answer of One side of a square loop (dimensions...

Question 50

One side of a square loop (dimensions of 15 cm * 15 cm) runs parallel to a current-carrying wire I_w = 5.0 A, and 3.0 A runs through the loop. The net force on the loop is 2.7 * 10^-6 N. The distance between the side of the loop and the wire is A) 5.0 cm. B) 10 cm. C) 15 cm. D) 20 cm.

Accepted Answer

The answer of One side of a square loop (dimensions...

Question 51

The magnetic dipole moment for a current I in a loop of area A is given by&#10;A) $\mu$ = I/A.&#10;B) $\mu$ = A/I.&#10;C) $\mu$ = 1/(IA).&#10;D) $\mu$ = IA.

Accepted Answer

The answer of The magnetic dipole moment for a current...

Deck 30: Charges and Currents in Magnetic Fields