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Deck 23: Electric Potential

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Question
Three negative charges of equal magnitudes are positioned along the x-axis at x = -a, x=0, and x = +a respectively. The charge located at x=0 is moved away along the y-axis to a position (x,y) = (0, +a). How does the potential energy of the system of charges change as a result?

A)The potential energy may increase or decrease depending on the magnitude of the charges.
B)The potential energy increases.
C)The potential energy decreases.
D)The potential energy stays the same.
E)More information is needed to answer the question.
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Question
A negative charge, if free, tries to move

A)from high potential to low potential.
B)from low potential to high potential.
C)toward infinity.
D)away from infinity.
E)in the direction of the electric field.
Question
The component of the electric field in any direction is equal to the negative of the rate of change of the electric potential with distance in that direction.
Question
For an electron moving in a direction opposite to the electric field

A)its potential energy increases and its electric potential decreases.
B)its potential energy decreases and its electric potential increases.
C)its potential energy increases and its electric potential increases.
D)its potential energy decreases and its electric potential decreases.
E)both its potential energy and it electric potential remain constant.
Question
The direction of an electric field is from higher to lower potential.
Question
A negative charge is moved from point A to point B along an equipotential surface. Which of the following statements is true for this case?

A)The negative charge performs work in moving from point A to point B.
B)Work is required to move the negative charge from point A to point B.
C)Work is both required and performed in moving the negative charge from point A to point B.
D)No work is required to move the negative charge from point A to point B.
E)Not enough information is given to make a statement about the work involved.
Question
For a proton moving in the direction of the electric field

A)its potential energy increases and its electric potential decreases.
B)its potential energy decreases and its electric potential increases.
C)its potential energy increases and its electric potential increases.
D)its potential energy decreases and its electric potential decreases.
E)both its potential energy and it electric potential remain constant.
Question
If the electric field is zero in some region of space is the electric potential zero there as well? Explain.
Question
An equipotential surface must be

A)parallel to the electric field at every point.
B)oriented 30° with respect to the electric field at every point.
C)oriented 60° with respect to the electric field at every point.
D)perpendicular to the electric field at every point.
E)equal to the electric field at every point.
Question
Every point on an equipotential surface is at the same potential.
Question
The potential outside a uniformly charged sphere is the same as if all the charge were concentrated at its center.
Question
When a proton moves in a direction of the electric field, its potential increases but its potential energy decreases.
Question
The potential of a uniformly charged sphere is lowest at

A)infinity.
B)a distance from the sphere equal to its radius.
C)a distance from the sphere equal to its diameter.
D)the surface of the sphere.
E)the center of the sphere.
Question
All points on the perpendicular bisector of the line joining two equal but opposite charges have a potential of zero.
Question
Explain why equipotential surfaces are always perpendicular to the electric field vectors.
Question
The direction in which the potential changes at the greatest rate is in the direction

A)of the gradient of the potential.
B)perpendicular to the electric field.
C)perpendicular to the gradient of the potential.
D)of the partial derivative with respect to x.
E)cannot be determined
Question
The change in electric potential energy, Ub - Ua, is the work done on a charge by the electric force as it moves from point a to point b.
Question
How much work is required to move a charge from one location on an equipotential to another point on the same equipotential? Explain.
Question
The work done in moving a positive charge against an electric field does not depend on the path chosen in moving the charge in that field. Based on the statement, what kind of force field is the electrostatic field?

A)discrete
B)quantized
C)polarized
D)conservative
E)nonconservative
Question
Equipotential lines and electric field lines meet perpendicular to one another.
Question
The electric potential at the origin of an xy-coordinate system is 40 V. A -8.0-μC charge is brought from x = +∞ to that point. What is the electric potential energy of this charge at the origin?

A)-3.2 × 10-4 J
B)3.2 × 10-4 J
C)-40 μJ
D)40 μJ
E)8.0 μJ
Question
The voltage between two parallel plates separated by a distance of 3.0 cm is 120 V. The electric field between the plates is

A)3.6 V/m.
B)up to 4000 V/m depending on position.
C)2000 V/m halfway between the plate.
D)4000 V/m.
E)7.2 V/m.
Question
Two uniformly distributed rings of charge, one of total charge Q1 and radius r1 and the other of total charge Q2 and radius r2, have the same center. The potential at the center is
Question
A charge Q distributed uniformly along the edge of a ring of radius R. What is the electric potential due to this charge at a distance x = R from the center the ring along its axis?
Question
If the electric field is 12 V/m in the positive x-direction, what is the potential difference between the origin, (0, 0), and the point (3.0 m, 4.0 m)?

A)48 V with the origin at the higher potential
B)48 V with the origin at the lower potential
C)36 V with the origin at the lower potential
D)36 V with the origin at the higher potential
E)cannot be determined
Question
If an electric field of magnitude 25 V/m makes an angle of 30° with a path of length 10 m, then the integral of E∙dl over this path has a value of

A)30 V.
B)250 V.
C)125 V.
D)217 V.
E)-250 V.
Question
FIGURE 23-1 <strong>FIGURE 23-1 Fig. 23-1 shows equipotentials surrounding a pair of charges Q<sub>A</sub> and Q<sub>B</sub>. The value of the potential half-way between the charges is indicated. Which of the statements below applies to the charges?</strong> A)The two charges have the same sign and equal magnitudes. B)Nothing can be said about the charges. C)The two charges have the same sign but different magnitudes. D)The two charges have opposite signs and equal magnitudes. E)The two charges have opposite signs and different magnitudes. <div style=padding-top: 35px>
Fig. 23-1 shows equipotentials surrounding a pair of charges QA and QB. The value of the potential half-way between the charges is indicated. Which of the statements below applies to the charges?

A)The two charges have the same sign and equal magnitudes.
B)Nothing can be said about the charges.
C)The two charges have the same sign but different magnitudes.
D)The two charges have opposite signs and equal magnitudes.
E)The two charges have opposite signs and different magnitudes.
Question
Computer monitors are often referred to as CRT's. CRT stands for

A)computer registration tube.
B)color relay transmission.
C)computer resource transmission.
D)nothing; it's computer jargon.
E)cathode ray tube.
Question
A half-ring (semicircle) of uniformly distributed charge Q has radius r. The potential at its center is
Question
An 800 V/m electric field is directed along the +x-axis. If the potential at x = 0 m is 2000 V, what is the potential at x = 2 m?

A)200 V
B)400 V
C)600 V
D)800 V
E)1000 V
Question
Two equal charges Q are separated by a distance d. One of the charges is released and moves away from the other due to the force between them. When the moving charge is a distance 3d from the other charge, what is its kinetic energy?
Question
One electron-volt corresponds to

A)8.0 × 10-20 J.
B)1.6 × 10-19 J.
C)9.5 × 10-17 J.
D)1.9 × 10-16 J.
Question
Electric dipoles always consist of two charges that are

A)equal in magnitude; opposite in sign.
B)equal in magnitude; both are negative.
C)equal in magnitude; both are positive.
D)unequal in magnitude; opposite in sign.
E)unequal in magnitude; both are negative.
Question
Cathode rays are now known to be

A)electrons.
B)visible light rays.
C)protons.
D)x-rays.
E)short wavelength light rays.
Question
At a certain point in space there is a potential of 400 V. What is the potential energy of a +2-μC charge at that point in space?

A)80 × 10-6 J
B)800 J
C)400 J
D)200 J
E)8 × 10-4 J
Question
FIGURE 23-2 FIGURE 23-2 Fig. 23-2 shows two arcs of a circle on which charges +Q and -Q have been spread uniformly. What is the value of the electric potential at the center of the circle?<div style=padding-top: 35px>
Fig. 23-2 shows two arcs of a circle on which charges +Q and -Q have been spread uniformly. What is the value of the electric potential at the center of the circle?
Question
At a certain point in space the electric potential is 20 V. A 4.0-μC charge is brought from infinity to that point. What is the electric potential energy of this charge at that point?

A)- 80 μJ
B)80 μJ
C)- 20 μJ
D)20 μJ
E)4.0 μJ
Question
Three electric charges QA = q, QB = -q, and QC = -2q are located at the points A (x = + a, y = 0), B (x = -a, y = 0), and C (x = 0, y = +2a) respectively. What is the value of the electric potential at the origin?
Question
The energy acquired by a particle carrying a charge equal to that on the electron as a result of moving through a potential difference of one volt is referred to as

A)a joule.
B)an electron-volt.
C)a proton-volt.
D)a neutron-volt.
E)a coulomb.
Question
FIGURE 23-3 FIGURE 23-3 Two point charges of magnitude +4.00 μC and +2.00 μC are placed at the opposite corners of a rectangle as shown in Fig. 23-3. (a) What is the potential at point A due to these charges? (b) What is the potential at point B due to these charges? (c) What is the potential difference between points A and B?<div style=padding-top: 35px>
Two point charges of magnitude +4.00 μC and +2.00 μC are placed at the opposite corners of a rectangle as shown in Fig. 23-3.
(a) What is the potential at point A due to these charges?
(b) What is the potential at point B due to these charges?
(c) What is the potential difference between points A and B?
Question
FIGURE 23-10 <strong>FIGURE 23-10 The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points G and D?</strong> A)+160 V B)-160 V C)+320 V D)0 V E)None of the other choices is correct. <div style=padding-top: 35px>
The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points G and D?

A)+160 V
B)-160 V
C)+320 V
D)0 V
E)None of the other choices is correct.
Question
FIGURE 23-12 <strong>FIGURE 23-12 Fig. 23-12 shows the variations of the electric potential V (in arbitrary units) as a function of the position x (also in arbitrary units). Which of the choices below correctly describes the orientation of the electric field along the x axis?</strong> A)E is positive from x = -2 to x = 2. B)E is positive from x = -2 to x = 0, and negative from 0 to x= 2. C)E is negative from x = -2 to x = 0, and positive from 0 to x= 2. D)E is negative from x = -2 to x = 2. E)More information is needed to answer the question. <div style=padding-top: 35px>
Fig. 23-12 shows the variations of the electric potential V (in arbitrary units) as a function of the position x (also in arbitrary units). Which of the choices below correctly describes the orientation of the electric field along the x axis?

A)E is positive from x = -2 to x = 2.
B)E is positive from x = -2 to x = 0, and negative from 0 to x= 2.
C)E is negative from x = -2 to x = 0, and positive from 0 to x= 2.
D)E is negative from x = -2 to x = 2.
E)More information is needed to answer the question.
Question
A charge of 1.5 μC is located at (0, 0) and a charge of 2.1 μC is located at (4 m, 0). What is the potential at (4 m, 3 m)?

A)7000 V
B)9000 V
C)9000 V at 37°
D)7000 V at 37°
E)cannot be determined
Question
Two charges QA = +q and QB = - 3q are located on the x-axis at x= 0 and x= d respectively. Where is the electric potential equal to zero?

A)x= 3d/4
B)x= d/3
C)x = d/4
D)x= 2d/3
E)x= d/2
Question
Two electric charges QA = + 1.0 μC and QB= - 2.0 μC are located 0.50 m apart. How much work is needed to move the charges apart and double the distance between them?

A)-36 × 10-3J
B)+18 × 10-3
C)0
D)+36 × 10-3
E)-18 × 10-3
Question
A large plate carries a uniform charge density σ = 8.85 × 10-9 C/ m2. A pattern showing equipotential surfaces with a 5 V potential difference would appear as

A)a series of planes perpendicular to the plate, 1 cm apart.
B)a series of lines perpendicular to the plate, 1 cm apart.
C)a series of lines parallel to the plate, 1 cm apart.
D)a series of circles of radius 1 cm, parallel to the plate.
E)a series of planes parallel to the plate, 1 cm apart.
Question
FIGURE 23-9 <strong>FIGURE 23-9 Two point charges of magnitude +4.0 μC and -4.0 μC are placed as shown in Fig. 23-9. What is the potential difference between points A and B?</strong> A)48 V B)96 V C)0 V D)96 × 10<sup>3</sup>V E)48 × 10<sup>3</sup>V <div style=padding-top: 35px>
Two point charges of magnitude +4.0 μC and -4.0 μC are placed as shown in Fig. 23-9. What is the potential difference between points A and B?

A)48 V
B)96 V
C)0 V
D)96 × 103V
E)48 × 103V
Question
FIGURE 23-11 <strong>FIGURE 23-11 Fig. 23-11 shows the variation of the electric potential V (measured in Volts) as a function of the radial direction r (measured in meters). For which range of r is the magnitude of the electric field the largest?</strong> A)from r = 2 m to r = 4 m B)from r = 4 m to r = 6 m C)from r = 0 to r = 2 m D)The magnitude of the field is the same everywhere. E)More information is needed to answer the question. <div style=padding-top: 35px>
Fig. 23-11 shows the variation of the electric potential V (measured in Volts) as a function of the radial direction r (measured in meters). For which range of r is the magnitude of the electric field the largest?

A)from r = 2 m to r = 4 m
B)from r = 4 m to r = 6 m
C)from r = 0 to r = 2 m
D)The magnitude of the field is the same everywhere.
E)More information is needed to answer the question.
Question
The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points A and G?

A)320 V
B)160 V
C)-160 V/m
D)0 V
E)None of the other choices is correct.
Question
FIGURE 23-4 <strong>FIGURE 23-4 Three point charges of -2.00 μC, +4.00 μC, and +6.00 μC are placed along the x axis as shown in Fig. 23-4. What is the electrical potential at point P due to these charges?</strong> A)-307 × 10<sup>3</sup>V B)+307 × 10<sup>3</sup>V C)-154 × 10<sup>3</sup>V D)+154 × 10<sup>3</sup>V E)0 V <div style=padding-top: 35px>
Three point charges of -2.00 μC, +4.00 μC, and +6.00 μC are placed along the x axis as shown in Fig. 23-4. What is the electrical potential at point P due to these charges?

A)-307 × 103V
B)+307 × 103V
C)-154 × 103V
D)+154 × 103V
E)0 V
Question
FIGURE 23-5 <strong>FIGURE 23-5 Four equal point charges of magnitude 6.00 μC are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-5. What is the electric potential of these charges at the center of this square?</strong> A)76.4 kV B)38.2 kV C)306 kV D)153 kV E)61.0 kV <div style=padding-top: 35px>
Four equal point charges of magnitude 6.00 μC are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-5. What is the electric potential of these charges at the center of this square?

A)76.4 kV
B)38.2 kV
C)306 kV
D)153 kV
E)61.0 kV
Question
FIGURE 23-8 <strong>FIGURE 23-8 Two charges of magnitude 6.0 μC, but opposite signs, are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-8. What is the electric potential at the vertex, P, of the triangle due to these charges?</strong> A)27 kV B)54 kV C)90 kV D)108 V E)0 V <div style=padding-top: 35px>
Two charges of magnitude 6.0 μC, but opposite signs, are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-8. What is the electric potential at the vertex, P, of the triangle due to these charges?

A)27 kV
B)54 kV
C)90 kV
D)108 V
E)0 V
Question
Four point charges, each of charge 2.5 x 10-5, are located on the x- and y-axes, one at each of the locations (0, 2.0 m), (0, -2.0 m), (2.0 m, 0), and (-2.0 m, 0). The potential at the origin is

A)2.3 × 105 V.
B)4.5 × 105 V.
C)3.5 × 105 V.
D)1.1 × 105 V.
E)0.
Question
FIGURE 23-6 <strong>FIGURE 23-6 Four equal point charges of magnitude 6.00 μC and of varying signs are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-6. What is the electric potential at the center of this square due to these charges?</strong> A)76.4 kV B)0 V C)153 kV D)61.0 kV E)306 kV <div style=padding-top: 35px>
Four equal point charges of magnitude 6.00 μC and of varying signs are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-6. What is the electric potential at the center of this square due to these charges?

A)76.4 kV
B)0 V
C)153 kV
D)61.0 kV
E)306 kV
Question
A +8.00-μC charge is situated along the +y-axis at y = 0.400 m. What is the electric potential at the origin because of this charge?

A)+180 × 103 V
B)-180 × 103 V
C)0 V
D)-288 × 103 V
E)+288 × 103 V
Question
Two charges QA = +2 μC and QB = - 6μC are located on the x-axis at xA= - 1 cm and xB= +2 cm respectively. Where should a third charge, QC = + 3μC, be placed on the positive x-axis so that the potential at the origin is equal to zero?

A)x = 4 cm
B)x = +1 cm
C)x =+2 cm
D)x = 3 cm
E)x = 5 cm
Question
FIGURE 23-7 <strong>FIGURE 23-7 Two identical charges of magnitude 6.0 μC are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-7. What is the electric potential at the vertex, P, of the triangle due to these charges?</strong> A)54 kV B)108 V C)0 V D)90 kV E)27 kV <div style=padding-top: 35px>
Two identical charges of magnitude 6.0 μC are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-7. What is the electric potential at the vertex, P, of the triangle due to these charges?

A)54 kV
B)108 V
C)0 V
D)90 kV
E)27 kV
Question
If the potential is given by 6/ x2, the x-component of the electric field is

A)-12 x-3.
B)-6x.
C)12 x-3.
D)12x.
E)6x.
Question
Two point charges of magnitude 4.0 μC and -4.0 μC are situated along the x-axis at x1 = 2.0 m and x2 = -2.0 m, respectively. What is the electric potential at the origin of the xy-coordinate system?

A)-36 × 103 V
B)0 V
C)36 × 103V
D)-48 × 103V
E)48 × 103V
Question
Three charges QA = -2.0 μC, QB= 6.0 μC, and QC= -4.0 μC are located along the y-axis at yA= -4.0 cm, yB = 0, and yC = 2.0 cm respectively. Calculate the electric potential at the point x = 6.0 cm on the x-axis.

A)0.81 × 105 V
B)-0.81 × 105 V
C)0.41 × 105 V
D)0
E)-0.41 × 105 V
Question
If a charge of 12 μC is located 5.0 cm from a charge of 6.5 μC, the potential energy of this arrangement is

A)1.4 × 10-5 J.
B)14 J.
C)0.
D)2.8 × 10-4 J.
E)281 J.
Question
If an electron is accelerated from rest through a potential difference of 25,000 volts in a color television picture tube, its kinetic energy will be

A)16 J.
B)2.5 × 104 J.
C)4.0 × 10-5J.
D)1.6 J.
E)4.0 × 10-15 J.
Question
Two point charges q1 = 4.0 μC and q2 = -8.0 μC are placed along the x-axis at x1 = 0 m and x2 = 0.20 m, respectively. What is the electric potential energy of this system of charges?

A)+1.4 J
B)-1.4 J
C)-32 J
D)4.0 J
E)-4.0 J
Question
The electric potential of a charge distribution is given by the equation V(x) = 3 x2 y2 + y z3 - 2 z3x, where x, y, z are measured in meters and V is measured in volts. Calculate the magnitude of the electric field vector at the position (x,y,z) = (1.0, 1.0, 1.0).

A)4.3 V/m
B)2.0 V/m
C)-8.1 V/m
D)8.6 V/m
E)74 V/m
Question
If the potential is given by V = xy - 3 z-2, then the electric field has a y-component of

A)x + y - 6 z-3.
B)-y.
C)-x.
D)x + y.
E)cannot be determined
Question
If a particle with a charge of 2 coulombs moves through a potential difference of 12 volts, its change in kinetic energy will a have magnitude of

A)12 J.
B)6 J.
C)8 J.
D)1/6 J.
E)24 J.
Question
If an electron is accelerated through a potential difference of 500 V between two parallel plates separated by a distance of 2.0 cm. The change in kinetic energy of the electron during this motion is

A)100 eV.
B)2000 eV.
C)250 eV.
D)500 eV.
E)1000 eV.
Question
The electric potential of a charge distribution is given by V(x, y) = 2xy - x2 - y. At which point is the electric field equal to zero?

A)x = 0.5, y = 1
B)x = 1, y = 1
C)x = 1, y = 0.5
D)x = 0.5, y = 0.5
E)x =0, y = 0
Question
Three equal charges of magnitude + 4.00 μC are placed at the corners of an equilateral triangle of side 2.00 cm. What is the electric potential energy of the system of these charges?

A)90.0 J
B)900 mJ
C)0 J
D)216 mJ
E)21.6 J
Question
An electron is accelerated from rest through a potential difference of 1000 volts giving it a kinetic energy of

A)1.6 × 10-22 eV.
B)0.001 eV.
C)1.6 × 10-16 J.
D)1.6 × 10-22 J.
E)1.6 × 10-16 eV.
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Deck 23: Electric Potential
1
Three negative charges of equal magnitudes are positioned along the x-axis at x = -a, x=0, and x = +a respectively. The charge located at x=0 is moved away along the y-axis to a position (x,y) = (0, +a). How does the potential energy of the system of charges change as a result?

A)The potential energy may increase or decrease depending on the magnitude of the charges.
B)The potential energy increases.
C)The potential energy decreases.
D)The potential energy stays the same.
E)More information is needed to answer the question.
The potential energy decreases.
2
A negative charge, if free, tries to move

A)from high potential to low potential.
B)from low potential to high potential.
C)toward infinity.
D)away from infinity.
E)in the direction of the electric field.
from low potential to high potential.
3
The component of the electric field in any direction is equal to the negative of the rate of change of the electric potential with distance in that direction.
True
4
For an electron moving in a direction opposite to the electric field

A)its potential energy increases and its electric potential decreases.
B)its potential energy decreases and its electric potential increases.
C)its potential energy increases and its electric potential increases.
D)its potential energy decreases and its electric potential decreases.
E)both its potential energy and it electric potential remain constant.
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5
The direction of an electric field is from higher to lower potential.
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6
A negative charge is moved from point A to point B along an equipotential surface. Which of the following statements is true for this case?

A)The negative charge performs work in moving from point A to point B.
B)Work is required to move the negative charge from point A to point B.
C)Work is both required and performed in moving the negative charge from point A to point B.
D)No work is required to move the negative charge from point A to point B.
E)Not enough information is given to make a statement about the work involved.
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7
For a proton moving in the direction of the electric field

A)its potential energy increases and its electric potential decreases.
B)its potential energy decreases and its electric potential increases.
C)its potential energy increases and its electric potential increases.
D)its potential energy decreases and its electric potential decreases.
E)both its potential energy and it electric potential remain constant.
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8
If the electric field is zero in some region of space is the electric potential zero there as well? Explain.
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9
An equipotential surface must be

A)parallel to the electric field at every point.
B)oriented 30° with respect to the electric field at every point.
C)oriented 60° with respect to the electric field at every point.
D)perpendicular to the electric field at every point.
E)equal to the electric field at every point.
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10
Every point on an equipotential surface is at the same potential.
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11
The potential outside a uniformly charged sphere is the same as if all the charge were concentrated at its center.
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12
When a proton moves in a direction of the electric field, its potential increases but its potential energy decreases.
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13
The potential of a uniformly charged sphere is lowest at

A)infinity.
B)a distance from the sphere equal to its radius.
C)a distance from the sphere equal to its diameter.
D)the surface of the sphere.
E)the center of the sphere.
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14
All points on the perpendicular bisector of the line joining two equal but opposite charges have a potential of zero.
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15
Explain why equipotential surfaces are always perpendicular to the electric field vectors.
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16
The direction in which the potential changes at the greatest rate is in the direction

A)of the gradient of the potential.
B)perpendicular to the electric field.
C)perpendicular to the gradient of the potential.
D)of the partial derivative with respect to x.
E)cannot be determined
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17
The change in electric potential energy, Ub - Ua, is the work done on a charge by the electric force as it moves from point a to point b.
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18
How much work is required to move a charge from one location on an equipotential to another point on the same equipotential? Explain.
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19
The work done in moving a positive charge against an electric field does not depend on the path chosen in moving the charge in that field. Based on the statement, what kind of force field is the electrostatic field?

A)discrete
B)quantized
C)polarized
D)conservative
E)nonconservative
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20
Equipotential lines and electric field lines meet perpendicular to one another.
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21
The electric potential at the origin of an xy-coordinate system is 40 V. A -8.0-μC charge is brought from x = +∞ to that point. What is the electric potential energy of this charge at the origin?

A)-3.2 × 10-4 J
B)3.2 × 10-4 J
C)-40 μJ
D)40 μJ
E)8.0 μJ
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22
The voltage between two parallel plates separated by a distance of 3.0 cm is 120 V. The electric field between the plates is

A)3.6 V/m.
B)up to 4000 V/m depending on position.
C)2000 V/m halfway between the plate.
D)4000 V/m.
E)7.2 V/m.
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23
Two uniformly distributed rings of charge, one of total charge Q1 and radius r1 and the other of total charge Q2 and radius r2, have the same center. The potential at the center is
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24
A charge Q distributed uniformly along the edge of a ring of radius R. What is the electric potential due to this charge at a distance x = R from the center the ring along its axis?
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25
If the electric field is 12 V/m in the positive x-direction, what is the potential difference between the origin, (0, 0), and the point (3.0 m, 4.0 m)?

A)48 V with the origin at the higher potential
B)48 V with the origin at the lower potential
C)36 V with the origin at the lower potential
D)36 V with the origin at the higher potential
E)cannot be determined
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26
If an electric field of magnitude 25 V/m makes an angle of 30° with a path of length 10 m, then the integral of E∙dl over this path has a value of

A)30 V.
B)250 V.
C)125 V.
D)217 V.
E)-250 V.
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27
FIGURE 23-1 <strong>FIGURE 23-1 Fig. 23-1 shows equipotentials surrounding a pair of charges Q<sub>A</sub> and Q<sub>B</sub>. The value of the potential half-way between the charges is indicated. Which of the statements below applies to the charges?</strong> A)The two charges have the same sign and equal magnitudes. B)Nothing can be said about the charges. C)The two charges have the same sign but different magnitudes. D)The two charges have opposite signs and equal magnitudes. E)The two charges have opposite signs and different magnitudes.
Fig. 23-1 shows equipotentials surrounding a pair of charges QA and QB. The value of the potential half-way between the charges is indicated. Which of the statements below applies to the charges?

A)The two charges have the same sign and equal magnitudes.
B)Nothing can be said about the charges.
C)The two charges have the same sign but different magnitudes.
D)The two charges have opposite signs and equal magnitudes.
E)The two charges have opposite signs and different magnitudes.
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28
Computer monitors are often referred to as CRT's. CRT stands for

A)computer registration tube.
B)color relay transmission.
C)computer resource transmission.
D)nothing; it's computer jargon.
E)cathode ray tube.
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29
A half-ring (semicircle) of uniformly distributed charge Q has radius r. The potential at its center is
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30
An 800 V/m electric field is directed along the +x-axis. If the potential at x = 0 m is 2000 V, what is the potential at x = 2 m?

A)200 V
B)400 V
C)600 V
D)800 V
E)1000 V
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31
Two equal charges Q are separated by a distance d. One of the charges is released and moves away from the other due to the force between them. When the moving charge is a distance 3d from the other charge, what is its kinetic energy?
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32
One electron-volt corresponds to

A)8.0 × 10-20 J.
B)1.6 × 10-19 J.
C)9.5 × 10-17 J.
D)1.9 × 10-16 J.
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33
Electric dipoles always consist of two charges that are

A)equal in magnitude; opposite in sign.
B)equal in magnitude; both are negative.
C)equal in magnitude; both are positive.
D)unequal in magnitude; opposite in sign.
E)unequal in magnitude; both are negative.
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34
Cathode rays are now known to be

A)electrons.
B)visible light rays.
C)protons.
D)x-rays.
E)short wavelength light rays.
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35
At a certain point in space there is a potential of 400 V. What is the potential energy of a +2-μC charge at that point in space?

A)80 × 10-6 J
B)800 J
C)400 J
D)200 J
E)8 × 10-4 J
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36
FIGURE 23-2 FIGURE 23-2 Fig. 23-2 shows two arcs of a circle on which charges +Q and -Q have been spread uniformly. What is the value of the electric potential at the center of the circle?
Fig. 23-2 shows two arcs of a circle on which charges +Q and -Q have been spread uniformly. What is the value of the electric potential at the center of the circle?
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37
At a certain point in space the electric potential is 20 V. A 4.0-μC charge is brought from infinity to that point. What is the electric potential energy of this charge at that point?

A)- 80 μJ
B)80 μJ
C)- 20 μJ
D)20 μJ
E)4.0 μJ
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38
Three electric charges QA = q, QB = -q, and QC = -2q are located at the points A (x = + a, y = 0), B (x = -a, y = 0), and C (x = 0, y = +2a) respectively. What is the value of the electric potential at the origin?
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39
The energy acquired by a particle carrying a charge equal to that on the electron as a result of moving through a potential difference of one volt is referred to as

A)a joule.
B)an electron-volt.
C)a proton-volt.
D)a neutron-volt.
E)a coulomb.
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40
FIGURE 23-3 FIGURE 23-3 Two point charges of magnitude +4.00 μC and +2.00 μC are placed at the opposite corners of a rectangle as shown in Fig. 23-3. (a) What is the potential at point A due to these charges? (b) What is the potential at point B due to these charges? (c) What is the potential difference between points A and B?
Two point charges of magnitude +4.00 μC and +2.00 μC are placed at the opposite corners of a rectangle as shown in Fig. 23-3.
(a) What is the potential at point A due to these charges?
(b) What is the potential at point B due to these charges?
(c) What is the potential difference between points A and B?
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41
FIGURE 23-10 <strong>FIGURE 23-10 The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points G and D?</strong> A)+160 V B)-160 V C)+320 V D)0 V E)None of the other choices is correct.
The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points G and D?

A)+160 V
B)-160 V
C)+320 V
D)0 V
E)None of the other choices is correct.
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42
FIGURE 23-12 <strong>FIGURE 23-12 Fig. 23-12 shows the variations of the electric potential V (in arbitrary units) as a function of the position x (also in arbitrary units). Which of the choices below correctly describes the orientation of the electric field along the x axis?</strong> A)E is positive from x = -2 to x = 2. B)E is positive from x = -2 to x = 0, and negative from 0 to x= 2. C)E is negative from x = -2 to x = 0, and positive from 0 to x= 2. D)E is negative from x = -2 to x = 2. E)More information is needed to answer the question.
Fig. 23-12 shows the variations of the electric potential V (in arbitrary units) as a function of the position x (also in arbitrary units). Which of the choices below correctly describes the orientation of the electric field along the x axis?

A)E is positive from x = -2 to x = 2.
B)E is positive from x = -2 to x = 0, and negative from 0 to x= 2.
C)E is negative from x = -2 to x = 0, and positive from 0 to x= 2.
D)E is negative from x = -2 to x = 2.
E)More information is needed to answer the question.
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43
A charge of 1.5 μC is located at (0, 0) and a charge of 2.1 μC is located at (4 m, 0). What is the potential at (4 m, 3 m)?

A)7000 V
B)9000 V
C)9000 V at 37°
D)7000 V at 37°
E)cannot be determined
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44
Two charges QA = +q and QB = - 3q are located on the x-axis at x= 0 and x= d respectively. Where is the electric potential equal to zero?

A)x= 3d/4
B)x= d/3
C)x = d/4
D)x= 2d/3
E)x= d/2
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45
Two electric charges QA = + 1.0 μC and QB= - 2.0 μC are located 0.50 m apart. How much work is needed to move the charges apart and double the distance between them?

A)-36 × 10-3J
B)+18 × 10-3
C)0
D)+36 × 10-3
E)-18 × 10-3
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46
A large plate carries a uniform charge density σ = 8.85 × 10-9 C/ m2. A pattern showing equipotential surfaces with a 5 V potential difference would appear as

A)a series of planes perpendicular to the plate, 1 cm apart.
B)a series of lines perpendicular to the plate, 1 cm apart.
C)a series of lines parallel to the plate, 1 cm apart.
D)a series of circles of radius 1 cm, parallel to the plate.
E)a series of planes parallel to the plate, 1 cm apart.
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47
FIGURE 23-9 <strong>FIGURE 23-9 Two point charges of magnitude +4.0 μC and -4.0 μC are placed as shown in Fig. 23-9. What is the potential difference between points A and B?</strong> A)48 V B)96 V C)0 V D)96 × 10<sup>3</sup>V E)48 × 10<sup>3</sup>V
Two point charges of magnitude +4.0 μC and -4.0 μC are placed as shown in Fig. 23-9. What is the potential difference between points A and B?

A)48 V
B)96 V
C)0 V
D)96 × 103V
E)48 × 103V
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48
FIGURE 23-11 <strong>FIGURE 23-11 Fig. 23-11 shows the variation of the electric potential V (measured in Volts) as a function of the radial direction r (measured in meters). For which range of r is the magnitude of the electric field the largest?</strong> A)from r = 2 m to r = 4 m B)from r = 4 m to r = 6 m C)from r = 0 to r = 2 m D)The magnitude of the field is the same everywhere. E)More information is needed to answer the question.
Fig. 23-11 shows the variation of the electric potential V (measured in Volts) as a function of the radial direction r (measured in meters). For which range of r is the magnitude of the electric field the largest?

A)from r = 2 m to r = 4 m
B)from r = 4 m to r = 6 m
C)from r = 0 to r = 2 m
D)The magnitude of the field is the same everywhere.
E)More information is needed to answer the question.
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49
The equipotential surfaces between two spherical conductors are shown in Fig. 23-10, with the value of the potential marked for each line. What is the potential difference between points A and G?

A)320 V
B)160 V
C)-160 V/m
D)0 V
E)None of the other choices is correct.
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50
FIGURE 23-4 <strong>FIGURE 23-4 Three point charges of -2.00 μC, +4.00 μC, and +6.00 μC are placed along the x axis as shown in Fig. 23-4. What is the electrical potential at point P due to these charges?</strong> A)-307 × 10<sup>3</sup>V B)+307 × 10<sup>3</sup>V C)-154 × 10<sup>3</sup>V D)+154 × 10<sup>3</sup>V E)0 V
Three point charges of -2.00 μC, +4.00 μC, and +6.00 μC are placed along the x axis as shown in Fig. 23-4. What is the electrical potential at point P due to these charges?

A)-307 × 103V
B)+307 × 103V
C)-154 × 103V
D)+154 × 103V
E)0 V
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51
FIGURE 23-5 <strong>FIGURE 23-5 Four equal point charges of magnitude 6.00 μC are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-5. What is the electric potential of these charges at the center of this square?</strong> A)76.4 kV B)38.2 kV C)306 kV D)153 kV E)61.0 kV
Four equal point charges of magnitude 6.00 μC are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-5. What is the electric potential of these charges at the center of this square?

A)76.4 kV
B)38.2 kV
C)306 kV
D)153 kV
E)61.0 kV
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52
FIGURE 23-8 <strong>FIGURE 23-8 Two charges of magnitude 6.0 μC, but opposite signs, are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-8. What is the electric potential at the vertex, P, of the triangle due to these charges?</strong> A)27 kV B)54 kV C)90 kV D)108 V E)0 V
Two charges of magnitude 6.0 μC, but opposite signs, are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-8. What is the electric potential at the vertex, P, of the triangle due to these charges?

A)27 kV
B)54 kV
C)90 kV
D)108 V
E)0 V
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53
Four point charges, each of charge 2.5 x 10-5, are located on the x- and y-axes, one at each of the locations (0, 2.0 m), (0, -2.0 m), (2.0 m, 0), and (-2.0 m, 0). The potential at the origin is

A)2.3 × 105 V.
B)4.5 × 105 V.
C)3.5 × 105 V.
D)1.1 × 105 V.
E)0.
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54
FIGURE 23-6 <strong>FIGURE 23-6 Four equal point charges of magnitude 6.00 μC and of varying signs are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-6. What is the electric potential at the center of this square due to these charges?</strong> A)76.4 kV B)0 V C)153 kV D)61.0 kV E)306 kV
Four equal point charges of magnitude 6.00 μC and of varying signs are placed at the corners of a square 2.00 m on each side, as shown in Fig. 23-6. What is the electric potential at the center of this square due to these charges?

A)76.4 kV
B)0 V
C)153 kV
D)61.0 kV
E)306 kV
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55
A +8.00-μC charge is situated along the +y-axis at y = 0.400 m. What is the electric potential at the origin because of this charge?

A)+180 × 103 V
B)-180 × 103 V
C)0 V
D)-288 × 103 V
E)+288 × 103 V
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56
Two charges QA = +2 μC and QB = - 6μC are located on the x-axis at xA= - 1 cm and xB= +2 cm respectively. Where should a third charge, QC = + 3μC, be placed on the positive x-axis so that the potential at the origin is equal to zero?

A)x = 4 cm
B)x = +1 cm
C)x =+2 cm
D)x = 3 cm
E)x = 5 cm
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57
FIGURE 23-7 <strong>FIGURE 23-7 Two identical charges of magnitude 6.0 μC are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-7. What is the electric potential at the vertex, P, of the triangle due to these charges?</strong> A)54 kV B)108 V C)0 V D)90 kV E)27 kV
Two identical charges of magnitude 6.0 μC are placed at the corners of the base of an equilateral triangle, as shown in Fig. 23-7. What is the electric potential at the vertex, P, of the triangle due to these charges?

A)54 kV
B)108 V
C)0 V
D)90 kV
E)27 kV
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58
If the potential is given by 6/ x2, the x-component of the electric field is

A)-12 x-3.
B)-6x.
C)12 x-3.
D)12x.
E)6x.
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59
Two point charges of magnitude 4.0 μC and -4.0 μC are situated along the x-axis at x1 = 2.0 m and x2 = -2.0 m, respectively. What is the electric potential at the origin of the xy-coordinate system?

A)-36 × 103 V
B)0 V
C)36 × 103V
D)-48 × 103V
E)48 × 103V
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60
Three charges QA = -2.0 μC, QB= 6.0 μC, and QC= -4.0 μC are located along the y-axis at yA= -4.0 cm, yB = 0, and yC = 2.0 cm respectively. Calculate the electric potential at the point x = 6.0 cm on the x-axis.

A)0.81 × 105 V
B)-0.81 × 105 V
C)0.41 × 105 V
D)0
E)-0.41 × 105 V
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61
If a charge of 12 μC is located 5.0 cm from a charge of 6.5 μC, the potential energy of this arrangement is

A)1.4 × 10-5 J.
B)14 J.
C)0.
D)2.8 × 10-4 J.
E)281 J.
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62
If an electron is accelerated from rest through a potential difference of 25,000 volts in a color television picture tube, its kinetic energy will be

A)16 J.
B)2.5 × 104 J.
C)4.0 × 10-5J.
D)1.6 J.
E)4.0 × 10-15 J.
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63
Two point charges q1 = 4.0 μC and q2 = -8.0 μC are placed along the x-axis at x1 = 0 m and x2 = 0.20 m, respectively. What is the electric potential energy of this system of charges?

A)+1.4 J
B)-1.4 J
C)-32 J
D)4.0 J
E)-4.0 J
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64
The electric potential of a charge distribution is given by the equation V(x) = 3 x2 y2 + y z3 - 2 z3x, where x, y, z are measured in meters and V is measured in volts. Calculate the magnitude of the electric field vector at the position (x,y,z) = (1.0, 1.0, 1.0).

A)4.3 V/m
B)2.0 V/m
C)-8.1 V/m
D)8.6 V/m
E)74 V/m
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65
If the potential is given by V = xy - 3 z-2, then the electric field has a y-component of

A)x + y - 6 z-3.
B)-y.
C)-x.
D)x + y.
E)cannot be determined
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66
If a particle with a charge of 2 coulombs moves through a potential difference of 12 volts, its change in kinetic energy will a have magnitude of

A)12 J.
B)6 J.
C)8 J.
D)1/6 J.
E)24 J.
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67
If an electron is accelerated through a potential difference of 500 V between two parallel plates separated by a distance of 2.0 cm. The change in kinetic energy of the electron during this motion is

A)100 eV.
B)2000 eV.
C)250 eV.
D)500 eV.
E)1000 eV.
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68
The electric potential of a charge distribution is given by V(x, y) = 2xy - x2 - y. At which point is the electric field equal to zero?

A)x = 0.5, y = 1
B)x = 1, y = 1
C)x = 1, y = 0.5
D)x = 0.5, y = 0.5
E)x =0, y = 0
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69
Three equal charges of magnitude + 4.00 μC are placed at the corners of an equilateral triangle of side 2.00 cm. What is the electric potential energy of the system of these charges?

A)90.0 J
B)900 mJ
C)0 J
D)216 mJ
E)21.6 J
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70
An electron is accelerated from rest through a potential difference of 1000 volts giving it a kinetic energy of

A)1.6 × 10-22 eV.
B)0.001 eV.
C)1.6 × 10-16 J.
D)1.6 × 10-22 J.
E)1.6 × 10-16 eV.
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