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Deck 3: Electric Potential

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Question
The electric field in a region is given by <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above <div style=padding-top: 35px> where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?

A) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above <div style=padding-top: 35px> V
B) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above <div style=padding-top: 35px> V
C) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above <div style=padding-top: 35px> V
D) - 6 V
E) none of the above
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Question
A uniform electric field exists between two parallel plates separated by 1.2 cm. The intensity of the field is 23 kN/C. What is the potential difference between the plates?

A) 7.5 MV
B) 3.0 MV
C) 15 kV
D) 0.30 kV
E) None of these is correct.
Question
<strong> Charges Q and q (Q \neq q), separated by a distance d, produce a potential V<sub>P</sub> = 0 at point P. This means that</strong> A) no force is acting on a test charge placed at point P. B) Q and q must have the same sign. C) the electric field must be zero at point P. D) the net work in bringing Q to distance d from q is zero. E) the net work needed to bring a charge from infinity to point P is zero. <div style=padding-top: 35px> Charges Q and q (Q \neq q), separated by a distance d, produce a potential VP = 0 at point P. This means that

A) no force is acting on a test charge placed at point P.
B) Q and q must have the same sign.
C) the electric field must be zero at point P.
D) the net work in bringing Q to distance d from q is zero.
E) the net work needed to bring a charge from infinity to point P is zero.
Question
The concept of difference in electric potential is most closely associated with

A) the mechanical force on an electron.
B) the number of atoms in one gram-atom.
C) the charge on one electron.
D) the resistance of a certain specified column of mercury.
E) the work per unit quantity of electricity.
Question
Two parallel metal plates 5.0 cm apart have a potential difference between them of
75 V. The electric force on a positive charge of 3.2 × 10-19 C at a point midway between the plates is approximately

A) 4.8 × 10-18 N
B) 2.4 × 10-17 N
C) 1.6 × 10-18 N
D) 4.8 × 10-16 N
E) 9.6 × 10-17 N
Question
When 5.0 C of charge moves at constant speed along a path between two points differing in potential by 12 V, the amount of work done is

A) 2.4 J
B) 0.42 J
C) 5.0 J
D) 12 J
E) 60 J
Question
The voltage between the cathode and the screen of a computer monitor is 12 kV. If we assume a speed of zero for an electron as it leaves the cathode, what is its speed just before it hits the screen?

A) 8.8 × 107 m/s
B) 6.5 × 107 m/s
C) 4.2 × 1015 m/s
D) 7.7 × 1015 m/s
E) 5.3 × 107 m/s
Question
The electric field in a region is given by <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 0) m?</strong> A) 8 V B) -8 V C) -16/3 V D) -24/3 V E) 11 V <div style=padding-top: 35px> where the units are in V/m. What is the potential from the origin to (x, y) = (2, 0) m?

A) 8 V
B) -8 V
C) -16/3 V
D) -24/3 V
E) 11 V
Question
A lithium nucleus with a charge of 3(1.6 × 10-19) C and a mass of 7(1.67 × 10-27) kg, and an alpha particle with a charge of 2(1.6 × 10-19) C and a mass of 4(1.67 × 10-27) kg, are at rest. They could be accelerated to the same kinetic energy by

A) accelerating them through the same electrical potential difference.
B) accelerating the alpha particle through V volts and the lithium nucleus through 2V/3 volts.
C) accelerating the alpha particle through V volts and the lithium nucleus through 7V/4 volts.
D) accelerating the alpha particle through V volts and the lithium nucleus through 7V/6 volts.
E) none of these procedures
Question
A charge of 2.0 mC is located in a uniform electric field of intensity 4.0 × 105 N/C. How much work is required to move this charge 20 cm along a path making an angle of 60° with the electric field?

A) 0.14 J
B) 0.34 J
C) 80 mJ
D) 14 J
E) 8.0 J
Question
The electron volt is a unit of

A) capacitance
B) charge
C) energy
D) momentum
E) potential
Question
Two parallel horizontal plates are spaced 0.40 cm apart in air. You introduce an oil droplet of mass 4.9 × 10-17 kg between the plates. If the droplet carries two electronic charges and if there were no air buoyancy, you could hold the droplet motionless between the plates if you kept the potential difference between them at

A) 60 V
B) 12 V
C) 3.0 V
D) 0.12 kV
E) 6.0 V
Question
When 2.0 C of charge moves at constant speed along a path between two points differing in potential by 6.0 V, the amount of work done is

A) 2 J
B) 3 J
C) 6 J
D) 12 J
E) 24 J
Question
Correct units for electric potential are

A) N/C
B) V/m
C) N/kg
D) J/C
E) C/N
Question
A uniform electric field exists between two parallel plates separated by 2.0 cm. The intensity of the field is 15 kN/C. What is the potential difference between the plates?

A) 0.75 MV
B) 30 kV
C) 15 kV
D) 0.30 kV
E) 54 kV
Question
The voltage between the cathode and the screen of a television set is 22 kV. If we assume a speed of zero for an electron as it leaves the cathode, what is its speed just before it hits the screen?

A) 8.8 × 107 m/s
B) 2.8 × 106 m/s
C) 6.2 × 107 m/s
D) 7.7 × 1015 m/s
E) 5.3 × 107 m/s
Question
Two parallel metal plates 0.35 cm apart have a potential difference between them of
175 V. The electric force on a positive charge of 6.4 × 10-19 C at a point midway between the plates is approximately

A) 4.8 × 10-18 N
B) 2.4 × 10-17 N
C) 1.6 × 10-18 N
D) 4.8 × 10-16 N
E) 3.2 × 10-14 N
Question
Two parallel horizontal plates are spaced 0.60 cm apart in air. You introduce an oil droplet of mass 7.4 × 10-17 kg between the plates. If the droplet carries five electronic charges and if there were no air buoyancy, you could hold the droplet motionless between the plates if you kept the potential difference between them at

A) 5.4 V
B) 27 V
C) 3.0 V
D) 0.54 V
E) 0.27 kV
Question
The electric field in a region is given by <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px> where Q is the charge. What is the potential between r = a to r = b?

A) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
B) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
C) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
D) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
E) none of the above
Question
A charge of 5.0 mC is located in a uniform electric field of intensity 3.5 × 105 N/C. How much work is required to move this charge 50 cm along a path making an angle of 33° with the electric field?

A) 0.27 J
B) 0.16 J
C) 0.54 J
D) 0.73 J
E) 7.3 mJ
Question
<strong> The electrostatic potential as a function of distance along a certain line in space is shown in graph (1). Which of the curves in graph (2) is most likely to represent the electric field as a function of distance along the same line?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The electrostatic potential as a function of distance along a certain line in space is shown in graph (1). Which of the curves in graph (2) is most likely to represent the electric field as a function of distance along the same line?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The work required to move a charge, q = +e from infinity to r = 2 m is</strong> A) 4000 eV B) 2000 eV C) 1000 eV D) 4000 eV E) zero <div style=padding-top: 35px> The electric field versus distance for a charge is plotted above. Use the reference point
V = 0 at r \rightarrow infinity.

-The work required to move a charge, q = +e from infinity to r = 2 m is

A) 4000 eV
B) 2000 eV
C) 1000 eV
D) <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The work required to move a charge, q = +e from infinity to r = 2 m is</strong> A) 4000 eV B) 2000 eV C) 1000 eV D) 4000 eV E) zero <div style=padding-top: 35px> 4000 eV
E) zero
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval. -The potential for line c is</strong> A) -100 V B) +100 V C) -200 V D) +200 V E) zero <div style=padding-top: 35px> Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval.

-The potential for line c is

A) -100 V
B) +100 V
C) -200 V
D) +200 V
E) zero
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: Which point in the electric field in the diagram is at the lowest potential?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px>
Which point in the electric field in the diagram is at the lowest potential?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: Which point in the electric field in the diagram is at the highest potential?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px>
Which point in the electric field in the diagram is at the highest potential?

A) 1
B) 2
C) 3
D) 4
E) 5
Question
The electrical potential 2.5 cm from a point charge of Q1 = +4.5 * 10-9 C and 2.0 cm from a second charge Q2 is 3.2 kV. Find Q2.

A) 2.7 F* 10-9 C
B) 4.4 * 10-9 C
C) 1.1 * 10-8 C
D) 3.5 * 10-9 C
E) 5.5 *10-9 C
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and C, and a charge of -3.2 × 10<sup>-</sup><sup>19</sup> C is placed at B. The electric potential at P is</strong> A) 2.2 V B) 9.4 V C) 29 V D) 0.43 nV E) 0.16 kV <div style=padding-top: 35px>
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and C, and a charge of -3.2 × 10-19 C is placed at B. The electric potential at P is

A) 2.2 V
B) 9.4 V
C) 29 V
D) 0.43 nV
E) 0.16 kV
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and B. The magnitude of the electric field at P is</strong> A) 9.1 × 10<sup>9</sup> N/C B) 6.8 × 10<sup>9</sup> N/C C) 1.2 × 10<sup>10</sup> N/C D) 2.6 × 10<sup>10</sup> N/C E) 3.3 × 10<sup>10</sup> N/C <div style=padding-top: 35px>
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and B. The magnitude of the electric field at P is

A) 9.1 × 109 N/C
B) 6.8 × 109 N/C
C) 1.2 × 1010 N/C
D) 2.6 × 1010 N/C
E) 3.3 × 1010 N/C
Question
The potential at a point due to a unit positive charge is found to be V. If the distance between the charge and the point is tripled, the potential becomes

A) V/3
B) 3V
C) V/9
D) 9V
E) 1/V2
Question
The electrical potential 2.0 cm from a point charge of Q1 = +6.5 *10-9 C and 3.5 cm from a second charge Q2 is 1.2 kV. Find Q2.

A) -6.7 * 10-9 C
B) -3.8 * 10-9 C
C) -1.0*10-9 C
D) 3.8 * 10-9 C
E) 1.0* 10-9 C
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval. -The work required to move a third charge, q = -e, from the+100 V line to b is</strong> A) -100 eV B) +100 eV C) -200 eV D) +200 eV E) zero <div style=padding-top: 35px> Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval.

-The work required to move a third charge, q = -e, from the+100 V line to b is

A) -100 eV
B) +100 eV
C) -200 eV
D) +200 eV
E) zero
Question
<strong> The figure shows two plates A and B. Plate A has a potential of 0 V and plate B a potential of 100 V. The dotted lines represent equipotential lines of 25, 50, and 75 V. A positive test charge of 1.6 × 10<sup>-</sup><sup>19</sup> C at point x is transferred to point z. The energy gained or expended by the test charge is</strong> A) 8 × 10<sup>-</sup><sup>18</sup> J, gained. B) 8 × 10<sup>-</sup><sup>18</sup> J, expended. C) 24 × 10<sup>-</sup><sup>18</sup> J, gained. D) 24 × 10<sup>-</sup><sup>8</sup> J, expended. E) 40 × 10<sup>-</sup><sup>8</sup> J, gained. <div style=padding-top: 35px> The figure shows two plates A and B. Plate A has a potential of 0 V and plate B a potential of 100 V. The dotted lines represent equipotential lines of 25, 50, and 75 V. A positive test charge of 1.6 × 10-19 C at point x is transferred to point z. The energy gained or expended by the test charge is

A) 8 × 10-18 J, gained.
B) 8 × 10-18 J, expended.
C) 24 × 10-18 J, gained.
D) 24 × 10-8 J, expended.
E) 40 × 10-8 J, gained.
Question
<strong> Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field and the electric potential V are determined at P, the center of the square, we find that</strong> A) E \neq 0 and V > 0 B) E = 0 and V = 0 C) E = 0 and V > 0 D) E \neq 0 and V < 0 E) None of these is correct. <div style=padding-top: 35px> Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field <strong> Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field and the electric potential V are determined at P, the center of the square, we find that</strong> A) E \neq 0 and V > 0 B) E = 0 and V = 0 C) E = 0 and V > 0 D) E \neq 0 and V < 0 E) None of these is correct. <div style=padding-top: 35px> and the electric potential V are determined at P, the center of the square, we find that

A) E \neq 0 and V > 0
B) E = 0 and V = 0
C) E = 0 and V > 0
D) E \neq 0 and V < 0
E) None of these is correct.
Question
Two charges Q1 (= +6 μ\mu C) and Q2 (= -2 μ\mu C) are brought from infinity to positions on the x-axis of x = -4 cm and x = +4 cm, respectively. How much work was done in bringing the charges together?

A) -1.80 * 106 J
B) -9.00 * 105 J
C) -16.9 J
D) -1.35 J
E) none of the above
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and B. The electric potential at P is approximately</strong> A) 2.9 V B) 3.6 V C) 6.5 V D) 9.3 V E) 1.5 V <div style=padding-top: 35px>
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and B. The electric potential at P is approximately

A) 2.9 V
B) 3.6 V
C) 6.5 V
D) 9.3 V
E) 1.5 V
Question
Use the following to answer the next question: <strong>Use the following to answer the next question: Which of the points shown in the diagram are at the same potential?</strong> A) 2 and 5 B) 2, 3, and 5 C) 1 and 4 D) 1 and 5 E) 2 and 4 <div style=padding-top: 35px>
Which of the points shown in the diagram are at the same potential?

A) 2 and 5
B) 2, 3, and 5
C) 1 and 4
D) 1 and 5
E) 2 and 4
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and C, and a charge of -3.2 × 10<sup>-</sup><sup>19</sup> C is placed at B. The magnitude of the electric field at P is approximately</strong> A) 1.7 × 10<sup>7</sup> N/C B) 10 × 10<sup>7</sup> N/C C) 4.5 × 10<sup>7</sup> N/C D) 2.3 × 10<sup>7</sup> N/C E) zero <div style=padding-top: 35px>
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and C, and a charge of -3.2 × 10-19 C is placed at B. The magnitude of the electric field at P is approximately

A) 1.7 × 107 N/C
B) 10 × 107 N/C
C) 4.5 × 107 N/C
D) 2.3 × 107 N/C
E) zero
Question
An electric dipole that has a positive charge of 4.8 × 10-19 C is separated from a negative charge of the same magnitude by 6.4 × 10-10 m. The electric potential at a point 9.2 × 10-10 m from each of the two charges is

A) 9.4 V
B) zero
C) 4.2 V
D) 5.1 × 109 V
E) 1.7 V
Question
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The potential for r < 1 m is</strong> A) 4000 V B) 2000 V C) 1000 V D) zero E) cannot be determined precisely <div style=padding-top: 35px> The electric field versus distance for a charge is plotted above. Use the reference point
V = 0 at r \rightarrow infinity.

-The potential for r < 1 m is

A) 4000 V
B) 2000 V
C) 1000 V
D) zero
E) cannot be determined precisely
Question
An electric dipole that has a positive charge of 4.80 × 10-19 C is separated from a negative charge of the same magnitude by 6.40 × 10-10 m. The magnitude of the electric field at the midpoint of the dipole is

A) zero
B) 27.0 N/C
C) 4.22 × 1010 N/C
D) 8.44 × 1010 N/C
E) 12.3 × 1010 N/C
Question
The electric potential in a region of space is given by V = 2xy + 3y2 in units of V. The electric field, in V/m, in this region is

A) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
B) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
C) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
D) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above <div style=padding-top: 35px>
E) none of the above
Question
The electric potential in a region of space is given by
V(x) = 50 V + (15 V/m) x.
The electric field in this region is

A) 50 V <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m) <div style=padding-top: 35px>
B) (15 V/m)x <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m) <div style=padding-top: 35px>
C) (50 V/m + 15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m) <div style=padding-top: 35px>
D) (15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m) <div style=padding-top: 35px>
E) -(15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m) <div style=padding-top: 35px>
Question
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The x-component of the electric field in this region is

A) (10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
C) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
D) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
E) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
Question
<strong> The graph that best represents the electric potential of a uniformly charged spherical shell as a function of the distance from the center of the shell is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The graph that best represents the electric potential of a uniformly charged spherical shell as a function of the distance from the center of the shell is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A disk of radius 10 cm has a uniform charge density of 20 nC/cm<sup>2</sup>. A small particle of mass m = 10 mg and charge q<sub>0</sub> = 5 nC is placed at x = 20 cm and released. The speed of the particle when it is a great distance from the disk is</strong> A) 14.2 cm/s B) 22.5 cm/s C) 42.9 cm/s D) 51.8 cm/s E) 66.1 cm/s <div style=padding-top: 35px>
A disk of radius 10 cm has a uniform charge density of 20 nC/cm2. A small particle of mass m = 10 mg and charge q0 = 5 nC is placed at x = 20 cm and released. The speed of the particle when it is a great distance from the disk is

A) 14.2 cm/s
B) 22.5 cm/s
C) 42.9 cm/s
D) 51.8 cm/s
E) 66.1 cm/s
Question
Two charges Q1 (= +6 μ\mu C) and Q2 (= -2 μ\mu C) are brought from infinity to positions on the x-axis of x = -4 cm and x = +4 cm, respectively. Is it possible to bring a third charge Q3 (= +3 μ\mu C) from infinity to a point on the x-axis between the charges where the potential is zero, and if so, where would this position be?

A) it is not possible
B) x = 0 cm
C) x = +2 cm
D) x = +6 cm
E) x = +1.5 cm
Question
<strong> An isolated hollow spherical conductor of radius R is carrying a charge of Q. Graph (1) represents the potential V as a function of the distance r from the center of the sphere. The graph that represents the electric field as a function of distance is</strong> A) 2 B) 3 C) 4 D) 5 E) 6 <div style=padding-top: 35px> An isolated hollow spherical conductor of radius R is carrying a charge of Q. Graph (1) represents the potential V as a function of the distance r from the center of the sphere. The graph that represents the electric field as a function of distance is

A) 2
B) 3
C) 4
D) 5
E) 6
Question
A proton (charge = e, mass = 1.67 *10-27 kg) with initial kinetic energy 3 MeV is fired head-on towards a fixed stationary uranium nucleus (charge 92e, mass = 3.95 * 10-25 kg). Calculate how close to the uranium the proton gets before it comes to rest. (Assume the uranium nucleus does not move.)

A) 2.75 * 105 m
B) 4.40 * 10-8 m
C) 4.40*10-14 m
D) 2.10 *10-7 m
E) none of the above
Question
<strong> The graph that represents the electric potential near an infinite plane of charge is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The graph that represents the electric potential near an infinite plane of charge is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Which of the following statements is true?

A) The gradient of the potential must be larger at a place where the electric field is stronger.
B) The gradient of the potential must be smaller at a place where the electric field is stronger.
C) The potential must be larger at a place where the electric field is stronger.
D) The potential must be smaller at a place where the electric field is stronger.
E) Local electric field strength is proportional to the local electrical potential.
Question
<strong> The figure depicts a uniform electric field. The direction in which the increase in the electric potential is a maximum is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The figure depicts a uniform electric field. The direction in which the increase in the electric potential is a maximum is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The y-component of the electric field in this region is

A) (10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
C) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
D) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
E) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m) <div style=padding-top: 35px>
Question
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The z-component of the electric field in this region is

A) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m) <div style=padding-top: 35px>
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m) <div style=padding-top: 35px>
C) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m) <div style=padding-top: 35px>
D) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m) <div style=padding-top: 35px>
E) (30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m) <div style=padding-top: 35px>
Question
The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x1 is given by

A) V(x1)
B) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E) <div style=padding-top: 35px>
C) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E) <div style=padding-top: 35px>
D) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E) <div style=padding-top: 35px>
E) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E) <div style=padding-top: 35px>
Question
The electric potential in a region of space is given by
V(x, y, z) = 50 V
The electric field in this region is

A) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V <div style=padding-top: 35px>
B) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V <div style=padding-top: 35px>
C) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V <div style=padding-top: 35px>
D) 0
E) 50 V
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A ring of radius 5 cm is the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. A small particle of mass m = 10 mg and charge q<sub>0</sub> = 5 nC is placed at x = 12 cm and released. The speed of the particle when it is a great distance from the ring is</strong> A) 1.36 cm/s B) 1.94 cm/s C) 2.63 cm/s D) 3.43 cm/s E) None of these is correct. <div style=padding-top: 35px>
A ring of radius 5 cm is the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. A small particle of mass m = 10 mg and charge q0 = 5 nC is placed at x = 12 cm and released. The speed of the particle when it is a great distance from the ring is

A) 1.36 cm/s
B) 1.94 cm/s
C) 2.63 cm/s
D) 3.43 cm/s
E) None of these is correct.
Question
<strong> The figure depicts a uniform electric field. The direction in which there is no change in the electric potential is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 <div style=padding-top: 35px> The figure depicts a uniform electric field. The direction in which there is no change in the electric potential is

A) 1
B) 2
C) 3
D) 4
E) 5
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A disk of radius 10 cm has a uniform charge density of 20 nC/cm<sup>2</sup>. The electric potential at a distance x = 20 cm on its axis is</strong> A) 189 kV B) 267 kV C) 302 kV D) 356 kV E) 421 kV <div style=padding-top: 35px>
A disk of radius 10 cm has a uniform charge density of 20 nC/cm2. The electric potential at a distance x = 20 cm on its axis is

A) 189 kV
B) 267 kV
C) 302 kV
D) 356 kV
E) 421 kV
Question
<strong> If the potential V of an array of charges versus the distance from the charges is as shown in graph 1, which graph shows the electric field E as a function of distance r?</strong> A) 2 B) 3 C) 4 D) 5 E) 6 <div style=padding-top: 35px> If the potential V of an array of charges versus the distance from the charges is as shown in graph 1, which graph shows the electric field E as a function of distance r?

A) 2
B) 3
C) 4
D) 5
E) 6
Question
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A ring of radius 5 cm is in the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. The electric potential at x = 12 cm is approximately</strong> A) 217 V B) 543 V C) 692 V D) 809 V E) 963 V <div style=padding-top: 35px>
A ring of radius 5 cm is in the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. The electric potential at x = 12 cm is approximately

A) 217 V
B) 543 V
C) 692 V
D) 809 V
E) 963 V
Question
The metal sphere at the top of a small Van de Graaf generator has a radius of 10 cm. How much charge can be accumulated on this sphere before dielectric breakdown of the air around it occurs? (The dielectric strength of air is 3.0 MV/m.)

A) 67 µC
B) 33 µC
C) 13 µC
D) 6.7 µC
E) 3.3 µC
Question
What is the approximate radius of an equipotential spherical surface of 100 V about a point charge of +45 nC if the potential at an infinite distance from the surface is zero?

A) 1.0 m
B) 2.1 m
C) 3.0 m
D) 4.5 m
E) 4.0 m
Question
<strong> Two charged metal spheres are connected by a wire. Sphere A is larger than sphere B, as shown. The magnitude of the electric potential of sphere A</strong> A) is greater than that at the surface of sphere B. B) is less than that at the surface of sphere B. C) is the same as that at the surface of sphere B. D) could be greater than or less than that at the surface of sphere B, depending on the radii of the spheres. E) could be greater than or less than that at the surface of sphere B, depending on the charges on the spheres. <div style=padding-top: 35px> Two charged metal spheres are connected by a wire. Sphere A is larger than sphere B, as shown. The magnitude of the electric potential of sphere A

A) is greater than that at the surface of sphere B.
B) is less than that at the surface of sphere B.
C) is the same as that at the surface of sphere B.
D) could be greater than or less than that at the surface of sphere B, depending on the radii of the spheres.
E) could be greater than or less than that at the surface of sphere B, depending on the charges on the spheres.
Question
A solid spherical conductor of radius 20 cm has a charge Q = 25 nC on it. A second, initially uncharged, spherical conductor of radius 12 cm is moved toward the first until they touch and is then moved far away from it. How much charge is there on the second sphere after the two spheres have been separated?

A) 15 nC
B) 9.4 nC
C) 25 nC
D) 3.9 nC
E) 2.1 nC
Question
<strong> A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 50 cm from the center of the spherical shell is</strong> A) 18 V B) 180 V C) 1800 V D) 18,000 V E) None of these is correct. <div style=padding-top: 35px> A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 50 cm from the center of the spherical shell is

A) 18 V
B) 180 V
C) 1800 V
D) 18,000 V
E) None of these is correct.
Question
The potential on the surface of a solid conducting sphere of radius r = 20 cm is 100 V. The potential at r = 10 cm is

A) 100 V
B) 50 V
C) 25 V
D) zero
E) cannot be determined
Question
Which of the following statements regarding potential is true?

A) The units of potential are N/C.
B) Potential is a vector quantity.
C) Equipotential surfaces are at right angles to lines of force.
D) Potential differences can be measured directly with a ballistic galvanometer.
E) Equipotential surfaces for an isolated point charge are cubes concentric with the charge.
Question
The metal sphere at the top of a small Van de Graaf generator has a radius of 8.0 cm. How much charge can be accumulated on this sphere before dielectric breakdown of the air around it occurs? (The dielectric strength of air is 3.0 MV/m.)

A) 2.1 µC
B) 3.3 µC
C) 1.3 nC
D) 6.7 µC
E) 4.2 µC
Question
The potential of a spherical shell carrying 6.0 μ\mu C of charge is 540 kV. What is the radius of the shell?

A) 1.0*101 m
B) 1.0 *102 m
C) 3.2 * 10-1 m
D) 1.0*10-1 m
E) none of the above
Question
A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 15 cm from the center of the spherical shell is

A) 18 V
B) 180 V
C) 1800 V
D) 18,000 V
E) None of these is correct.
Question
<strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is

A) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
B) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
C) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
D) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
E) None of these is correct.
Question
The electric potential at the surface of an infinite plane of charge is 100 V. If the charge density of the charge on the infinite plane is s σ\sigma = 1 nC/m2, the electric potential at a distance of 1 m from the infinite plane is

A) 22.3 V
B) 43.5 V
C) 50.0 V
D) 65.7 V
E) 83.4 V
Question
What is the approximate radius of an equipotential spherical surface of 30 V about a point charge of +15 nC if the potential at an infinite distance from the surface is zero?

A) 1.0 m
B) 2.1 m
C) 3.0 m
D) 4.5 m
E) 6.8 m
Question
A solid spherical conductor of radius 15 cm has a charge Q = 6.5 nC on it. A second, initially uncharged, spherical conductor of radius 10 cm is moved toward the first until they touch and is then moved far away from it. How much charge is there on the second sphere after the two spheres have been separated?

A) 2.6 nC
B) 2.2 nC
C) 3.2 nC
D) 3.9 nC
E) 4.3 nC
Question
The dielectric strength of the atmosphere is of the order of

A) 1 V/m
B) 102 V/m
C) 104 V/m
D) 106 V/m
E) 108 V/m
Question
A conducting sphere of radius r1 = 10 cm and charge q1 = 2 μ\mu C is placed far apart from a second conducting sphere of radius r2 = 30 cm and charge q2 = 3 μ\mu C. The two spheres are then connected by a thin conducting wire. What is the potential on the surface of the first sphere after the two spheres are connected by the wire? Use the reference V = 0 for r at infinity.

A) 1.12 *105 V
B) 1.80*105 V
C) 2.25 * 105 V
D) 2.70 *105 V
E) none of the above
Question
<strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is

A) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
B) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
C) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
D) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. <div style=padding-top: 35px>
E) None of these is correct.
Question
<strong> The figure shows portions of four equipotential surfaces whose potentials are related as follows: V<sub>1</sub> > V<sub>2</sub> > V<sub>3</sub> > V<sub>4</sub>. The lines represent four paths (A \rightarrow A', B \rightarrow B', C \rightarrow C', D \rightarrow D') along which equal test charges are moved. The work involved can be said to be</strong> A) the greatest for path A \rightarrow A'. B) the greatest for path B \rightarrow B'. C) the greatest for path C \rightarrow C'. D) the greatest for path D \rightarrow D'. E) the same for all paths. <div style=padding-top: 35px> The figure shows portions of four equipotential surfaces whose potentials are related as follows: V1 > V2 > V3 > V4. The lines represent four paths (A \rightarrow A', B \rightarrow B', C \rightarrow C', D \rightarrow D') along which equal test charges are moved. The work involved can be said to be

A) the greatest for path A \rightarrow A'.
B) the greatest for path B \rightarrow B'.
C) the greatest for path C \rightarrow C'.
D) the greatest for path D \rightarrow D'.
E) the same for all paths.
Question
A conducting sphere of radius r1 = 10 cm and charge q1 = 2 μ\mu C is placed far apart from a second conducting sphere of radius r2 = 30 cm and charge q2 = 3 μ\mu C. The two spheres are then connected by a thin conducting wire. What is the charge on the first sphere after the two spheres are connected by the wire?

A) 2 μ\mu C
B) 2.5 μ\mu C
C) 3 μ\mu C
D) 1.25 μ\mu C
E) none of the above
Question
The charge density of an infinite line of charge is λ\lambda = 100 nC/m. If zero of potential is chosen to be at a point having a perpendicular distance of 1 m from the line, the electric potential at a perpendicular distance of 50 cm from this line is

A) 1.25 kV
B) 2.34 kV
C) 0
D) -1.25 kV
E) -2.34 kV
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Deck 3: Electric Potential
1
The electric field in a region is given by <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?

A) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above V
B) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above V
C) <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 2) m?</strong> A) V B) V C) V D) - 6 V E) none of the above V
D) - 6 V
E) none of the above
V V
2
A uniform electric field exists between two parallel plates separated by 1.2 cm. The intensity of the field is 23 kN/C. What is the potential difference between the plates?

A) 7.5 MV
B) 3.0 MV
C) 15 kV
D) 0.30 kV
E) None of these is correct.
None of these is correct.
3
<strong> Charges Q and q (Q \neq q), separated by a distance d, produce a potential V<sub>P</sub> = 0 at point P. This means that</strong> A) no force is acting on a test charge placed at point P. B) Q and q must have the same sign. C) the electric field must be zero at point P. D) the net work in bringing Q to distance d from q is zero. E) the net work needed to bring a charge from infinity to point P is zero. Charges Q and q (Q \neq q), separated by a distance d, produce a potential VP = 0 at point P. This means that

A) no force is acting on a test charge placed at point P.
B) Q and q must have the same sign.
C) the electric field must be zero at point P.
D) the net work in bringing Q to distance d from q is zero.
E) the net work needed to bring a charge from infinity to point P is zero.
the net work needed to bring a charge from infinity to point P is zero.
4
The concept of difference in electric potential is most closely associated with

A) the mechanical force on an electron.
B) the number of atoms in one gram-atom.
C) the charge on one electron.
D) the resistance of a certain specified column of mercury.
E) the work per unit quantity of electricity.
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5
Two parallel metal plates 5.0 cm apart have a potential difference between them of
75 V. The electric force on a positive charge of 3.2 × 10-19 C at a point midway between the plates is approximately

A) 4.8 × 10-18 N
B) 2.4 × 10-17 N
C) 1.6 × 10-18 N
D) 4.8 × 10-16 N
E) 9.6 × 10-17 N
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6
When 5.0 C of charge moves at constant speed along a path between two points differing in potential by 12 V, the amount of work done is

A) 2.4 J
B) 0.42 J
C) 5.0 J
D) 12 J
E) 60 J
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7
The voltage between the cathode and the screen of a computer monitor is 12 kV. If we assume a speed of zero for an electron as it leaves the cathode, what is its speed just before it hits the screen?

A) 8.8 × 107 m/s
B) 6.5 × 107 m/s
C) 4.2 × 1015 m/s
D) 7.7 × 1015 m/s
E) 5.3 × 107 m/s
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8
The electric field in a region is given by <strong>The electric field in a region is given by where the units are in V/m. What is the potential from the origin to (x, y) = (2, 0) m?</strong> A) 8 V B) -8 V C) -16/3 V D) -24/3 V E) 11 V where the units are in V/m. What is the potential from the origin to (x, y) = (2, 0) m?

A) 8 V
B) -8 V
C) -16/3 V
D) -24/3 V
E) 11 V
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9
A lithium nucleus with a charge of 3(1.6 × 10-19) C and a mass of 7(1.67 × 10-27) kg, and an alpha particle with a charge of 2(1.6 × 10-19) C and a mass of 4(1.67 × 10-27) kg, are at rest. They could be accelerated to the same kinetic energy by

A) accelerating them through the same electrical potential difference.
B) accelerating the alpha particle through V volts and the lithium nucleus through 2V/3 volts.
C) accelerating the alpha particle through V volts and the lithium nucleus through 7V/4 volts.
D) accelerating the alpha particle through V volts and the lithium nucleus through 7V/6 volts.
E) none of these procedures
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10
A charge of 2.0 mC is located in a uniform electric field of intensity 4.0 × 105 N/C. How much work is required to move this charge 20 cm along a path making an angle of 60° with the electric field?

A) 0.14 J
B) 0.34 J
C) 80 mJ
D) 14 J
E) 8.0 J
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11
The electron volt is a unit of

A) capacitance
B) charge
C) energy
D) momentum
E) potential
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12
Two parallel horizontal plates are spaced 0.40 cm apart in air. You introduce an oil droplet of mass 4.9 × 10-17 kg between the plates. If the droplet carries two electronic charges and if there were no air buoyancy, you could hold the droplet motionless between the plates if you kept the potential difference between them at

A) 60 V
B) 12 V
C) 3.0 V
D) 0.12 kV
E) 6.0 V
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13
When 2.0 C of charge moves at constant speed along a path between two points differing in potential by 6.0 V, the amount of work done is

A) 2 J
B) 3 J
C) 6 J
D) 12 J
E) 24 J
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14
Correct units for electric potential are

A) N/C
B) V/m
C) N/kg
D) J/C
E) C/N
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15
A uniform electric field exists between two parallel plates separated by 2.0 cm. The intensity of the field is 15 kN/C. What is the potential difference between the plates?

A) 0.75 MV
B) 30 kV
C) 15 kV
D) 0.30 kV
E) 54 kV
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16
The voltage between the cathode and the screen of a television set is 22 kV. If we assume a speed of zero for an electron as it leaves the cathode, what is its speed just before it hits the screen?

A) 8.8 × 107 m/s
B) 2.8 × 106 m/s
C) 6.2 × 107 m/s
D) 7.7 × 1015 m/s
E) 5.3 × 107 m/s
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17
Two parallel metal plates 0.35 cm apart have a potential difference between them of
175 V. The electric force on a positive charge of 6.4 × 10-19 C at a point midway between the plates is approximately

A) 4.8 × 10-18 N
B) 2.4 × 10-17 N
C) 1.6 × 10-18 N
D) 4.8 × 10-16 N
E) 3.2 × 10-14 N
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18
Two parallel horizontal plates are spaced 0.60 cm apart in air. You introduce an oil droplet of mass 7.4 × 10-17 kg between the plates. If the droplet carries five electronic charges and if there were no air buoyancy, you could hold the droplet motionless between the plates if you kept the potential difference between them at

A) 5.4 V
B) 27 V
C) 3.0 V
D) 0.54 V
E) 0.27 kV
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19
The electric field in a region is given by <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above where Q is the charge. What is the potential between r = a to r = b?

A) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above
B) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above
C) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above
D) <strong>The electric field in a region is given by where Q is the charge. What is the potential between r = a to r = b?</strong> A) B) C) D) E) none of the above
E) none of the above
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20
A charge of 5.0 mC is located in a uniform electric field of intensity 3.5 × 105 N/C. How much work is required to move this charge 50 cm along a path making an angle of 33° with the electric field?

A) 0.27 J
B) 0.16 J
C) 0.54 J
D) 0.73 J
E) 7.3 mJ
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21
<strong> The electrostatic potential as a function of distance along a certain line in space is shown in graph (1). Which of the curves in graph (2) is most likely to represent the electric field as a function of distance along the same line?</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The electrostatic potential as a function of distance along a certain line in space is shown in graph (1). Which of the curves in graph (2) is most likely to represent the electric field as a function of distance along the same line?

A) 1
B) 2
C) 3
D) 4
E) 5
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22
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The work required to move a charge, q = +e from infinity to r = 2 m is</strong> A) 4000 eV B) 2000 eV C) 1000 eV D) 4000 eV E) zero The electric field versus distance for a charge is plotted above. Use the reference point
V = 0 at r \rightarrow infinity.

-The work required to move a charge, q = +e from infinity to r = 2 m is

A) 4000 eV
B) 2000 eV
C) 1000 eV
D) <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The work required to move a charge, q = +e from infinity to r = 2 m is</strong> A) 4000 eV B) 2000 eV C) 1000 eV D) 4000 eV E) zero 4000 eV
E) zero
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23
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval. -The potential for line c is</strong> A) -100 V B) +100 V C) -200 V D) +200 V E) zero Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval.

-The potential for line c is

A) -100 V
B) +100 V
C) -200 V
D) +200 V
E) zero
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24
Use the following to answer the next question: <strong>Use the following to answer the next question: Which point in the electric field in the diagram is at the lowest potential?</strong> A) 1 B) 2 C) 3 D) 4 E) 5
Which point in the electric field in the diagram is at the lowest potential?

A) 1
B) 2
C) 3
D) 4
E) 5
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25
Use the following to answer the next question: <strong>Use the following to answer the next question: Which point in the electric field in the diagram is at the highest potential?</strong> A) 1 B) 2 C) 3 D) 4 E) 5
Which point in the electric field in the diagram is at the highest potential?

A) 1
B) 2
C) 3
D) 4
E) 5
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26
The electrical potential 2.5 cm from a point charge of Q1 = +4.5 * 10-9 C and 2.0 cm from a second charge Q2 is 3.2 kV. Find Q2.

A) 2.7 F* 10-9 C
B) 4.4 * 10-9 C
C) 1.1 * 10-8 C
D) 3.5 * 10-9 C
E) 5.5 *10-9 C
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27
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and C, and a charge of -3.2 × 10<sup>-</sup><sup>19</sup> C is placed at B. The electric potential at P is</strong> A) 2.2 V B) 9.4 V C) 29 V D) 0.43 nV E) 0.16 kV
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and C, and a charge of -3.2 × 10-19 C is placed at B. The electric potential at P is

A) 2.2 V
B) 9.4 V
C) 29 V
D) 0.43 nV
E) 0.16 kV
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28
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and B. The magnitude of the electric field at P is</strong> A) 9.1 × 10<sup>9</sup> N/C B) 6.8 × 10<sup>9</sup> N/C C) 1.2 × 10<sup>10</sup> N/C D) 2.6 × 10<sup>10</sup> N/C E) 3.3 × 10<sup>10</sup> N/C
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and B. The magnitude of the electric field at P is

A) 9.1 × 109 N/C
B) 6.8 × 109 N/C
C) 1.2 × 1010 N/C
D) 2.6 × 1010 N/C
E) 3.3 × 1010 N/C
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29
The potential at a point due to a unit positive charge is found to be V. If the distance between the charge and the point is tripled, the potential becomes

A) V/3
B) 3V
C) V/9
D) 9V
E) 1/V2
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30
The electrical potential 2.0 cm from a point charge of Q1 = +6.5 *10-9 C and 3.5 cm from a second charge Q2 is 1.2 kV. Find Q2.

A) -6.7 * 10-9 C
B) -3.8 * 10-9 C
C) -1.0*10-9 C
D) 3.8 * 10-9 C
E) 1.0* 10-9 C
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31
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval. -The work required to move a third charge, q = -e, from the+100 V line to b is</strong> A) -100 eV B) +100 eV C) -200 eV D) +200 eV E) zero Two equal positive charges are placed x m apart. The equipotential lines are at 100 V interval.

-The work required to move a third charge, q = -e, from the+100 V line to b is

A) -100 eV
B) +100 eV
C) -200 eV
D) +200 eV
E) zero
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32
<strong> The figure shows two plates A and B. Plate A has a potential of 0 V and plate B a potential of 100 V. The dotted lines represent equipotential lines of 25, 50, and 75 V. A positive test charge of 1.6 × 10<sup>-</sup><sup>19</sup> C at point x is transferred to point z. The energy gained or expended by the test charge is</strong> A) 8 × 10<sup>-</sup><sup>18</sup> J, gained. B) 8 × 10<sup>-</sup><sup>18</sup> J, expended. C) 24 × 10<sup>-</sup><sup>18</sup> J, gained. D) 24 × 10<sup>-</sup><sup>8</sup> J, expended. E) 40 × 10<sup>-</sup><sup>8</sup> J, gained. The figure shows two plates A and B. Plate A has a potential of 0 V and plate B a potential of 100 V. The dotted lines represent equipotential lines of 25, 50, and 75 V. A positive test charge of 1.6 × 10-19 C at point x is transferred to point z. The energy gained or expended by the test charge is

A) 8 × 10-18 J, gained.
B) 8 × 10-18 J, expended.
C) 24 × 10-18 J, gained.
D) 24 × 10-8 J, expended.
E) 40 × 10-8 J, gained.
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33
<strong> Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field and the electric potential V are determined at P, the center of the square, we find that</strong> A) E \neq 0 and V > 0 B) E = 0 and V = 0 C) E = 0 and V > 0 D) E \neq 0 and V < 0 E) None of these is correct. Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field <strong> Charges +Q and -Q are arranged at the corners of a square as shown. When the electric field and the electric potential V are determined at P, the center of the square, we find that</strong> A) E \neq 0 and V > 0 B) E = 0 and V = 0 C) E = 0 and V > 0 D) E \neq 0 and V < 0 E) None of these is correct. and the electric potential V are determined at P, the center of the square, we find that

A) E \neq 0 and V > 0
B) E = 0 and V = 0
C) E = 0 and V > 0
D) E \neq 0 and V < 0
E) None of these is correct.
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34
Two charges Q1 (= +6 μ\mu C) and Q2 (= -2 μ\mu C) are brought from infinity to positions on the x-axis of x = -4 cm and x = +4 cm, respectively. How much work was done in bringing the charges together?

A) -1.80 * 106 J
B) -9.00 * 105 J
C) -16.9 J
D) -1.35 J
E) none of the above
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35
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and B. The electric potential at P is approximately</strong> A) 2.9 V B) 3.6 V C) 6.5 V D) 9.3 V E) 1.5 V
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and B. The electric potential at P is approximately

A) 2.9 V
B) 3.6 V
C) 6.5 V
D) 9.3 V
E) 1.5 V
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36
Use the following to answer the next question: <strong>Use the following to answer the next question: Which of the points shown in the diagram are at the same potential?</strong> A) 2 and 5 B) 2, 3, and 5 C) 1 and 4 D) 1 and 5 E) 2 and 4
Which of the points shown in the diagram are at the same potential?

A) 2 and 5
B) 2, 3, and 5
C) 1 and 4
D) 1 and 5
E) 2 and 4
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37
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and BP = 0.80 nm. Charges of +3.2 × 10<sup>-</sup><sup>19</sup> C are placed at A and C, and a charge of -3.2 × 10<sup>-</sup><sup>19</sup> C is placed at B. The magnitude of the electric field at P is approximately</strong> A) 1.7 × 10<sup>7</sup> N/C B) 10 × 10<sup>7</sup> N/C C) 4.5 × 10<sup>7</sup> N/C D) 2.3 × 10<sup>7</sup> N/C E) zero
ABC is a straight line with AB = BC = 0.60 nm. BP is perpendicular to ABC and
BP = 0.80 nm. Charges of +3.2 × 10-19 C are placed at A and C, and a charge of -3.2 × 10-19 C is placed at B. The magnitude of the electric field at P is approximately

A) 1.7 × 107 N/C
B) 10 × 107 N/C
C) 4.5 × 107 N/C
D) 2.3 × 107 N/C
E) zero
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38
An electric dipole that has a positive charge of 4.8 × 10-19 C is separated from a negative charge of the same magnitude by 6.4 × 10-10 m. The electric potential at a point 9.2 × 10-10 m from each of the two charges is

A) 9.4 V
B) zero
C) 4.2 V
D) 5.1 × 109 V
E) 1.7 V
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39
Use the following figure to answer the next problem: <strong>Use the following figure to answer the next problem: The electric field versus distance for a charge is plotted above. Use the reference point V = 0 at r \rightarrow infinity. -The potential for r < 1 m is</strong> A) 4000 V B) 2000 V C) 1000 V D) zero E) cannot be determined precisely The electric field versus distance for a charge is plotted above. Use the reference point
V = 0 at r \rightarrow infinity.

-The potential for r < 1 m is

A) 4000 V
B) 2000 V
C) 1000 V
D) zero
E) cannot be determined precisely
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40
An electric dipole that has a positive charge of 4.80 × 10-19 C is separated from a negative charge of the same magnitude by 6.40 × 10-10 m. The magnitude of the electric field at the midpoint of the dipole is

A) zero
B) 27.0 N/C
C) 4.22 × 1010 N/C
D) 8.44 × 1010 N/C
E) 12.3 × 1010 N/C
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41
The electric potential in a region of space is given by V = 2xy + 3y2 in units of V. The electric field, in V/m, in this region is

A) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above
B) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above
C) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above
D) <strong>The electric potential in a region of space is given by V = 2xy + 3y<sup>2</sup> in units of V. The electric field, in V/m, in this region is</strong> A) B) C) D) E) none of the above
E) none of the above
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42
The electric potential in a region of space is given by
V(x) = 50 V + (15 V/m) x.
The electric field in this region is

A) 50 V <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m)
B) (15 V/m)x <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m)
C) (50 V/m + 15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m)
D) (15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m)
E) -(15 V/m) <strong>The electric potential in a region of space is given by V(x) = 50 V + (15 V/m) x. The electric field in this region is</strong> A) 50 V B) (15 V/m)x C) (50 V/m + 15 V/m) D) (15 V/m) E) -(15 V/m)
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43
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The x-component of the electric field in this region is

A) (10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m)
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m)
C) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m)
D) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m)
E) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The x-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) -(30 V/m)
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44
<strong> The graph that best represents the electric potential of a uniformly charged spherical shell as a function of the distance from the center of the shell is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The graph that best represents the electric potential of a uniformly charged spherical shell as a function of the distance from the center of the shell is

A) 1
B) 2
C) 3
D) 4
E) 5
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45
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A disk of radius 10 cm has a uniform charge density of 20 nC/cm<sup>2</sup>. A small particle of mass m = 10 mg and charge q<sub>0</sub> = 5 nC is placed at x = 20 cm and released. The speed of the particle when it is a great distance from the disk is</strong> A) 14.2 cm/s B) 22.5 cm/s C) 42.9 cm/s D) 51.8 cm/s E) 66.1 cm/s
A disk of radius 10 cm has a uniform charge density of 20 nC/cm2. A small particle of mass m = 10 mg and charge q0 = 5 nC is placed at x = 20 cm and released. The speed of the particle when it is a great distance from the disk is

A) 14.2 cm/s
B) 22.5 cm/s
C) 42.9 cm/s
D) 51.8 cm/s
E) 66.1 cm/s
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46
Two charges Q1 (= +6 μ\mu C) and Q2 (= -2 μ\mu C) are brought from infinity to positions on the x-axis of x = -4 cm and x = +4 cm, respectively. Is it possible to bring a third charge Q3 (= +3 μ\mu C) from infinity to a point on the x-axis between the charges where the potential is zero, and if so, where would this position be?

A) it is not possible
B) x = 0 cm
C) x = +2 cm
D) x = +6 cm
E) x = +1.5 cm
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47
<strong> An isolated hollow spherical conductor of radius R is carrying a charge of Q. Graph (1) represents the potential V as a function of the distance r from the center of the sphere. The graph that represents the electric field as a function of distance is</strong> A) 2 B) 3 C) 4 D) 5 E) 6 An isolated hollow spherical conductor of radius R is carrying a charge of Q. Graph (1) represents the potential V as a function of the distance r from the center of the sphere. The graph that represents the electric field as a function of distance is

A) 2
B) 3
C) 4
D) 5
E) 6
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48
A proton (charge = e, mass = 1.67 *10-27 kg) with initial kinetic energy 3 MeV is fired head-on towards a fixed stationary uranium nucleus (charge 92e, mass = 3.95 * 10-25 kg). Calculate how close to the uranium the proton gets before it comes to rest. (Assume the uranium nucleus does not move.)

A) 2.75 * 105 m
B) 4.40 * 10-8 m
C) 4.40*10-14 m
D) 2.10 *10-7 m
E) none of the above
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49
<strong> The graph that represents the electric potential near an infinite plane of charge is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The graph that represents the electric potential near an infinite plane of charge is

A) 1
B) 2
C) 3
D) 4
E) 5
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50
Which of the following statements is true?

A) The gradient of the potential must be larger at a place where the electric field is stronger.
B) The gradient of the potential must be smaller at a place where the electric field is stronger.
C) The potential must be larger at a place where the electric field is stronger.
D) The potential must be smaller at a place where the electric field is stronger.
E) Local electric field strength is proportional to the local electrical potential.
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51
<strong> The figure depicts a uniform electric field. The direction in which the increase in the electric potential is a maximum is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The figure depicts a uniform electric field. The direction in which the increase in the electric potential is a maximum is

A) 1
B) 2
C) 3
D) 4
E) 5
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52
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The y-component of the electric field in this region is

A) (10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m)
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m)
C) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m)
D) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m)
E) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The y-component of the electric field in this region is</strong> A) (10 V/m) B) -(10 V/m) C) -(20 V/m) D) (20 V/m) E) -(30 V/m)
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53
The electric potential in a region of space is given by
V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z
The z-component of the electric field in this region is

A) -(30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m)
B) -(10 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m)
C) (20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m)
D) -(20 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m)
E) (30 V/m) <strong>The electric potential in a region of space is given by V(x, y, z) = (10 V/m) x + (20 V/m) y + (30 V/m) z The z-component of the electric field in this region is</strong> A) -(30 V/m) B) -(10 V/m) C) (20 V/m) D) -(20 V/m) E) (30 V/m)
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54
The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x1 is given by

A) V(x1)
B) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E)
C) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E)
D) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E)
E) <strong>The electric potential is known to be a function of x only; i.e., v = V(x). The electric field at a position x<sub>1</sub> is given by</strong> A) V(x<sub>1</sub>) B) C) D) E)
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55
The electric potential in a region of space is given by
V(x, y, z) = 50 V
The electric field in this region is

A) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V
B) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V
C) 50 V <strong>The electric potential in a region of space is given by V(x, y, z) = 50 V The electric field in this region is</strong> A) 50 V B) 50 V C) 50 V D) 0 E) 50 V
D) 0
E) 50 V
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56
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A ring of radius 5 cm is the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. A small particle of mass m = 10 mg and charge q<sub>0</sub> = 5 nC is placed at x = 12 cm and released. The speed of the particle when it is a great distance from the ring is</strong> A) 1.36 cm/s B) 1.94 cm/s C) 2.63 cm/s D) 3.43 cm/s E) None of these is correct.
A ring of radius 5 cm is the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. A small particle of mass m = 10 mg and charge q0 = 5 nC is placed at x = 12 cm and released. The speed of the particle when it is a great distance from the ring is

A) 1.36 cm/s
B) 1.94 cm/s
C) 2.63 cm/s
D) 3.43 cm/s
E) None of these is correct.
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57
<strong> The figure depicts a uniform electric field. The direction in which there is no change in the electric potential is</strong> A) 1 B) 2 C) 3 D) 4 E) 5 The figure depicts a uniform electric field. The direction in which there is no change in the electric potential is

A) 1
B) 2
C) 3
D) 4
E) 5
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58
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A disk of radius 10 cm has a uniform charge density of 20 nC/cm<sup>2</sup>. The electric potential at a distance x = 20 cm on its axis is</strong> A) 189 kV B) 267 kV C) 302 kV D) 356 kV E) 421 kV
A disk of radius 10 cm has a uniform charge density of 20 nC/cm2. The electric potential at a distance x = 20 cm on its axis is

A) 189 kV
B) 267 kV
C) 302 kV
D) 356 kV
E) 421 kV
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59
<strong> If the potential V of an array of charges versus the distance from the charges is as shown in graph 1, which graph shows the electric field E as a function of distance r?</strong> A) 2 B) 3 C) 4 D) 5 E) 6 If the potential V of an array of charges versus the distance from the charges is as shown in graph 1, which graph shows the electric field E as a function of distance r?

A) 2
B) 3
C) 4
D) 5
E) 6
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60
Use the following figure to answer the next four problems: <strong>Use the following figure to answer the next four problems: A ring of radius 5 cm is in the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. The electric potential at x = 12 cm is approximately</strong> A) 217 V B) 543 V C) 692 V D) 809 V E) 963 V
A ring of radius 5 cm is in the yz plane with its center at the origin. The ring carries a uniform charge of 10 nC. The electric potential at x = 12 cm is approximately

A) 217 V
B) 543 V
C) 692 V
D) 809 V
E) 963 V
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61
The metal sphere at the top of a small Van de Graaf generator has a radius of 10 cm. How much charge can be accumulated on this sphere before dielectric breakdown of the air around it occurs? (The dielectric strength of air is 3.0 MV/m.)

A) 67 µC
B) 33 µC
C) 13 µC
D) 6.7 µC
E) 3.3 µC
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62
What is the approximate radius of an equipotential spherical surface of 100 V about a point charge of +45 nC if the potential at an infinite distance from the surface is zero?

A) 1.0 m
B) 2.1 m
C) 3.0 m
D) 4.5 m
E) 4.0 m
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63
<strong> Two charged metal spheres are connected by a wire. Sphere A is larger than sphere B, as shown. The magnitude of the electric potential of sphere A</strong> A) is greater than that at the surface of sphere B. B) is less than that at the surface of sphere B. C) is the same as that at the surface of sphere B. D) could be greater than or less than that at the surface of sphere B, depending on the radii of the spheres. E) could be greater than or less than that at the surface of sphere B, depending on the charges on the spheres. Two charged metal spheres are connected by a wire. Sphere A is larger than sphere B, as shown. The magnitude of the electric potential of sphere A

A) is greater than that at the surface of sphere B.
B) is less than that at the surface of sphere B.
C) is the same as that at the surface of sphere B.
D) could be greater than or less than that at the surface of sphere B, depending on the radii of the spheres.
E) could be greater than or less than that at the surface of sphere B, depending on the charges on the spheres.
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64
A solid spherical conductor of radius 20 cm has a charge Q = 25 nC on it. A second, initially uncharged, spherical conductor of radius 12 cm is moved toward the first until they touch and is then moved far away from it. How much charge is there on the second sphere after the two spheres have been separated?

A) 15 nC
B) 9.4 nC
C) 25 nC
D) 3.9 nC
E) 2.1 nC
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65
<strong> A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 50 cm from the center of the spherical shell is</strong> A) 18 V B) 180 V C) 1800 V D) 18,000 V E) None of these is correct. A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 50 cm from the center of the spherical shell is

A) 18 V
B) 180 V
C) 1800 V
D) 18,000 V
E) None of these is correct.
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66
The potential on the surface of a solid conducting sphere of radius r = 20 cm is 100 V. The potential at r = 10 cm is

A) 100 V
B) 50 V
C) 25 V
D) zero
E) cannot be determined
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67
Which of the following statements regarding potential is true?

A) The units of potential are N/C.
B) Potential is a vector quantity.
C) Equipotential surfaces are at right angles to lines of force.
D) Potential differences can be measured directly with a ballistic galvanometer.
E) Equipotential surfaces for an isolated point charge are cubes concentric with the charge.
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68
The metal sphere at the top of a small Van de Graaf generator has a radius of 8.0 cm. How much charge can be accumulated on this sphere before dielectric breakdown of the air around it occurs? (The dielectric strength of air is 3.0 MV/m.)

A) 2.1 µC
B) 3.3 µC
C) 1.3 nC
D) 6.7 µC
E) 4.2 µC
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69
The potential of a spherical shell carrying 6.0 μ\mu C of charge is 540 kV. What is the radius of the shell?

A) 1.0*101 m
B) 1.0 *102 m
C) 3.2 * 10-1 m
D) 1.0*10-1 m
E) none of the above
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70
A charge of 100 nC resides on the surface of a spherical shell of radius 20 cm. The electric potential at a distance of 15 cm from the center of the spherical shell is

A) 18 V
B) 180 V
C) 1800 V
D) 18,000 V
E) None of these is correct.
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71
<strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct. The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is

A) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
B) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
C) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
D) <strong> The vector that best represents the direction of the electric field intensity at point x on the 20-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
E) None of these is correct.
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72
The electric potential at the surface of an infinite plane of charge is 100 V. If the charge density of the charge on the infinite plane is s σ\sigma = 1 nC/m2, the electric potential at a distance of 1 m from the infinite plane is

A) 22.3 V
B) 43.5 V
C) 50.0 V
D) 65.7 V
E) 83.4 V
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73
What is the approximate radius of an equipotential spherical surface of 30 V about a point charge of +15 nC if the potential at an infinite distance from the surface is zero?

A) 1.0 m
B) 2.1 m
C) 3.0 m
D) 4.5 m
E) 6.8 m
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74
A solid spherical conductor of radius 15 cm has a charge Q = 6.5 nC on it. A second, initially uncharged, spherical conductor of radius 10 cm is moved toward the first until they touch and is then moved far away from it. How much charge is there on the second sphere after the two spheres have been separated?

A) 2.6 nC
B) 2.2 nC
C) 3.2 nC
D) 3.9 nC
E) 4.3 nC
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75
The dielectric strength of the atmosphere is of the order of

A) 1 V/m
B) 102 V/m
C) 104 V/m
D) 106 V/m
E) 108 V/m
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76
A conducting sphere of radius r1 = 10 cm and charge q1 = 2 μ\mu C is placed far apart from a second conducting sphere of radius r2 = 30 cm and charge q2 = 3 μ\mu C. The two spheres are then connected by a thin conducting wire. What is the potential on the surface of the first sphere after the two spheres are connected by the wire? Use the reference V = 0 for r at infinity.

A) 1.12 *105 V
B) 1.80*105 V
C) 2.25 * 105 V
D) 2.70 *105 V
E) none of the above
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77
<strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct. The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is

A) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
B) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
C) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
D) <strong> The vector that best represents the direction of the electric field intensity at point x on the 200-V equipotential line is</strong> A) B) C) D) E) None of these is correct.
E) None of these is correct.
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78
<strong> The figure shows portions of four equipotential surfaces whose potentials are related as follows: V<sub>1</sub> > V<sub>2</sub> > V<sub>3</sub> > V<sub>4</sub>. The lines represent four paths (A \rightarrow A', B \rightarrow B', C \rightarrow C', D \rightarrow D') along which equal test charges are moved. The work involved can be said to be</strong> A) the greatest for path A \rightarrow A'. B) the greatest for path B \rightarrow B'. C) the greatest for path C \rightarrow C'. D) the greatest for path D \rightarrow D'. E) the same for all paths. The figure shows portions of four equipotential surfaces whose potentials are related as follows: V1 > V2 > V3 > V4. The lines represent four paths (A \rightarrow A', B \rightarrow B', C \rightarrow C', D \rightarrow D') along which equal test charges are moved. The work involved can be said to be

A) the greatest for path A \rightarrow A'.
B) the greatest for path B \rightarrow B'.
C) the greatest for path C \rightarrow C'.
D) the greatest for path D \rightarrow D'.
E) the same for all paths.
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79
A conducting sphere of radius r1 = 10 cm and charge q1 = 2 μ\mu C is placed far apart from a second conducting sphere of radius r2 = 30 cm and charge q2 = 3 μ\mu C. The two spheres are then connected by a thin conducting wire. What is the charge on the first sphere after the two spheres are connected by the wire?

A) 2 μ\mu C
B) 2.5 μ\mu C
C) 3 μ\mu C
D) 1.25 μ\mu C
E) none of the above
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80
The charge density of an infinite line of charge is λ\lambda = 100 nC/m. If zero of potential is chosen to be at a point having a perpendicular distance of 1 m from the line, the electric potential at a perpendicular distance of 50 cm from this line is

A) 1.25 kV
B) 2.34 kV
C) 0
D) -1.25 kV
E) -2.34 kV
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