PHY: Chap 22

A charged particle is placed in an electric field that varies with location. No force is exerted on this charge: A. at locations where the electric field is zero B. at locations where the electric field strength is 1/(1.6 × 10^−19)N/C C. if the particle is moving along a field line D. if the particle is moving perpendicularly to a field line E. if the field is caused by an equal amount of positive and negative charge

A

Experimenter A uses a test charge q0 and experimenter B uses a test charge −2q0 to measure an electric field produced by stationary charges. A finds a field that is: A. the same in both magnitude and direction as the field found by B B. greater in magnitude than the field found by B C. less in magnitude than the field found by B D. opposite in direction to the field found by B E. either greater or less than the field found by B, depending on the accelerations of the test charges

A

The magnitude of the force of a 400-N/C electric field on a 0.02-C point charge is: A. 8.0N B. 8 × 10^−5 N C. 8 × 10^−3 N D. 0.08N E. 2 × 1011 N

A

The units of the electric field are: A. J/(C·m) B. J/C C. J·C D. J/m E. none of these

A

Two point particles, with the same charge, are located at two vertices of an equilateral triangle. A third charged particle is placed so the electric field at the third vertex is zero. The third particle must: A. be on the perpendicular bisector of the line joining the first two charges B. be on the line joining the first two charges C. have the same charge as the first two particles D. have charge of the same magnitude as the first two charges but its charge may have a different sign E. be at the center of the triangle

A

Two thin spherical shells, one with radius R and the other with radius 2R, surround an isolated charged point particle. The ratio of the number of field lines through the larger sphere to the number through the smaller is: A. 1 B. 2 C. 4 D. 1/2 E. 1/4

A

An electric dipole consists of a particle with a charge of +6×10^−6 C at the origin and a particle with a charge of −6 × 10^−6 Conthe x axis at x =3 × 10^−3 m. Its dipole moment is: A. 1.8 × 10^−8 C · m, in the positive x direction B. 1.8 × 10^−8 C · m, in the negative x direction C. 0 because the net charge is 0 D. 1.8 × 10^−8 C · m, in the positive y direction E. 1.8 × 10^−8 C · m, in the negative y direction

B

An electric field exerts a torque on a dipole only if: A. the field is parallel to the dipole moment B. the field is not parallel to the dipole moment C. the field is perpendicular to the dipole moment D. the field is not perpendicular to the dipole moment E. the field is uniform

B

An electron traveling north enters a region where the electric field is uniform and points north. The electron: A. speeds up B. slows down C. veers east D. veers west E. continues with the same speed in the same direction

B

Choose the correct statement concerning electric field lines: A. field lines may cross B. field lines are close together where the field is large C. field lines point away from a negatively charged particle D. a charged point particle released from rest moves along a field line E. none of these are correct

B

The purpose of Milliken's oil drop experiment was to determine: A. the mass of an electron B. the charge of an electron C. the ratio of charge to mass for an electron D. the sign of the charge on an electron E. viscosity

B

When the dipole moment of a dipole in a uniform electric field rotates to become more nearly aligned with the field: A. the field does positive work and the potential energy increases B. the field does positive work and the potential energy decreases C. the field does negative work and the potential energy increases D. the field does negative work and the potential energy decreases E. the field does no work

B

A uniform electric field of 300N/C makes an angle of 25◦ with the dipole moment of an electric dipole. If the torque exerted by the field has a magnitude of 2.5×10^−7 N·m, the dipole moment must be: A. 8.3 × 10^−10 C · m B. 9.2 × 10^−10 C · m C. 2.0 × 10^−9 C · m D. 8.3 × 10^−5 C · m E. 1.8 × 10^−4 C · m

C

An electron traveling north enters a region where the electric field is uniform and points west. The electron: A. speeds up B. slows down C. veers east D. veers west E. continues with the same speed in the same direction

C

An isolated charged point particle produces an electric field with magnitude E at a point 2m away. At a point 1m from the particle the magnitude of the field is: A. E B. 2E C. 4E D. E/2 E. E/4

C

The torque exerted by an electric field on a dipole is: A. parallel to the field and perpendicular to the dipole moment B. parallel to both the field and dipole moment C. perpendicular to both the field and dipole moment D. parallel to the dipole moment and perpendicular to the field E. not related to the directions of the field and dipole moment

C

Two point particles, with a charges of q1 and q2, are placed a distance r apart. The electric field is zero at a point P between the particles on the line segment connecting them. We conclude that: A. q1 and q2 must have the same magnitude and sign B. P must be midway between the particles C. q1 and q2 must have the same sign but may have different magnitudes D. q1 and q2 must have equal magnitudes and opposite signs E. q1 and q2 must have opposite signs and may have different magnitudes

C

A 200-N/C electric field is in the positive x direction. The force on an electron in this field is: A. 200N in the positive x direction B. 200N in the negative x direction C. 3.2 × 10^−17 N in the positive x direction D. 3.2 × 10^−17 N in the negative x direction E. 0

D

A charged oil drop with a mass of 2 × 10^−4 kg is held suspended by a downward electric field of 300N/C. The charge on the drop is: A. +1.5 × 10^−6 C B. −1.5 × 10^−6 C C. +6.5 × 10^−6 C D. −6.5 × 10^−6 C E. 0

D

An electric field is most directly related to: A. the momentum of a test charge B. the kinetic energy of a test charge C. the potential energy of a test charge D. the force acting on a test charge E. the charge carried by a test charge

D

An isolated charged point particle produces an electric field with magnitude E at a point 2m away from the charge. A point at which the field magnitude is E/4 is: A. 1m away from the particle B. 0.5m away from the particle C. 2m away from the particle D. 4m away from the particle E. 8m away from the particle

D

Let k denote 1/4π60. The magnitude of the electric field at a distance r from an isolated point particle with charge q is: A. kq/r B. kr/q C. kq/r^3 D. kq/r^2 E. kq^2/r^2

D

The dipole moment of a dipole in a 300-N/C electric field is initially perpendicular to the field, but it rotates so it is in the same direction as the field. If the moment has a magnitude of 2 × 10^−9 C · m, the work done by the field is: A. −12 × 10^−7 J B. −6 × 10^−7 J C. 0 D. 6 × 10^−7 J E. 12 × 10^−7 J

D

The electric field at a distance of 10 cm from an isolated point particle with a charge of 2×10^−9 C is: A. 1.8N/C B. 180N/C C. 18N/C D. 1800N/C E. none of these

D

The electric field due to a uniform distribution of charge on a spherical shell is zero: A. everywhere B. nowhere C. only at the center of the shell D. only inside the shell E. only outside the shell

D

The units of the electric field are: A. N · C^2 B. C/N C. N D. N/C E. C/m^2

D

A certain physics textbook shows a region of space in which two electric field lines cross each other. We conclude that: A. at least two point charges are present B. an electrical conductor is present C. an insulator is present D. the field points in two directions at the same place E. the author made a mistake

E

As used in the definition of electric field, a "test charge": A. has zero charge B. has charge of magnitude 1C C. has charge of magnitude 1.6 × 10−19 C D. must be an electron E. none of the above

E

Electric field lines: A. are trajectories of a test charge B. are vectors in the direction of the electric field C. form closed loops D. cross each other in the region between two point charges E. are none of the above

E

The force exerted by a uniform electric field on a dipole is: A. parallel to the dipole moment B. perpendicular to the dipole moment C. parallel to the electric field D. perpendicular to the electric field E. none of the above

E

Two charged point particles are located at two vertices of an equilateral triangle and the electric field is zero at the third vertex. We conclude: A. the two particles have charges with opposite signs and the same magnitude B. the two particles have charges with opposite signs and different magnitudes C. the two particles have identical charges D. the two particles have charges with the same sign but different magnitudes E. at least one other charged particle is present

E

Two point particles, one with charge +8 × 10^−9 C and the other with charge −2 × 10^−9 C, are separated by 4m. The electric field in N/C midway between them is: A. 9 × 109 B. 13, 500 C. 135, 000 D. 36 × 10^−9 E. 22.5

E