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Deck 17: Temperature and Heat

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Question
Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become <strong>Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become </strong> A) d. B) 2d. C) 4d. D) 8d. <div style=padding-top: 35px>

A) <strong>Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become </strong> A) d. B) 2d. C) 4d. D) 8d. <div style=padding-top: 35px> d.
B) 2d.
C) 4d.
D) 8d.
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Question
Coulomb's law: A 1.0-C point charge is 15 m from a second point charge, and the electric force on one of them due to the other is 1.0 N. What is the magnitude of the second charge? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 25 C
B) 1.0 C
C) 10 nC
D) 0.025 C
E) 25 nC
Question
Electric field of multiple point-charges: The figure shows three electric charges labeled Q1, Q2, Q3, and some electric field lines in the region surrounding the charges. What are the signs of the three charges? <strong>Electric field of multiple point-charges: The figure shows three electric charges labeled Q<sub>1</sub>, Q<sub>2</sub>, Q<sub>3</sub>, and some electric field lines in the region surrounding the charges. What are the signs of the three charges? </strong> A) Q<sub>1</sub> is positive, Q<sub>2</sub> is negative, Q<sub>3</sub> is positive. B) Q<sub>1</sub> is negative, Q<sub>2</sub> is positive, Q<sub>3</sub> is negative. C) Q<sub>1</sub> is positive, Q<sub>2</sub> is positive, Q<sub>3</sub> is negative. D) All three charges are negative. E) All three charges are positive. <div style=padding-top: 35px>

A) Q1 is positive, Q2 is negative, Q3 is positive.
B) Q1 is negative, Q2 is positive, Q3 is negative.
C) Q1 is positive, Q2 is positive, Q3 is negative.
D) All three charges are negative.
E) All three charges are positive.
Question
Charge: A piece of plastic has a net charge of +2.00 μC. How many more protons than electrons does this piece of plastic have? (e = 1.60 × 10-19C)

A) 1.25 × 1013
B) 1.25 × 1019
C) 2.50 × 1013
D) 2.50 × 1019
Question
Motion of a charged particle: An electron is initially moving to the right when it enters a uniform electric field directed upwards. Which trajectory shown below will the electron follow? <strong>Motion of a charged particle: An electron is initially moving to the right when it enters a uniform electric field directed upwards. Which trajectory shown below will the electron follow? </strong> A) trajectory W B) trajectory X C) trajectory Y D) trajectory Z <div style=padding-top: 35px>

A) trajectory W
B) trajectory X
C) trajectory Y
D) trajectory Z
Question
Parallel plates: Two large, flat, horizontally oriented plates are parallel to each other, a distance d apart. Half way between the two plates the electric field has magnitude E. If the separation of the plates is reduced to d/2 what is the magnitude of the electric field half way between the plates?

A) 4E
B) 2E
C) E
D) 0
E) E/2
Question
Coulomb's law: Charge Q1 = 6.0 nC is at (0.30 m, 0), charge Q2 = -1.0 nC is at (0, 0.10 m), and charge Q3 = 5.0 nC is at (0, 0). What are the magnitude and direction of the net electrostatic force on the 5.0-nC charge due to the other charges? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
Question
Electric field of multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d as shown in the figure. Which of the arrows represents the direction of the net electric field at the center of the square? <strong>Electric field of multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d as shown in the figure. Which of the arrows represents the direction of the net electric field at the center of the square? </strong> A) A B) B C) C D) D E) The field is equal to zero at point P. <div style=padding-top: 35px>

A) A
B) B
C) C
D) D
E) The field is equal to zero at point P.
Question
Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). <strong>Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). Sphere Y is now moved away from X, as in Figure (b). What are the final charge states of X and Y?</strong> A) Both X and Y are neutral. B) X is positive and Y is neutral. C) X is neutral and Y is positive. D) X is negative and Y is positive. E) Both X and Y are negative. <div style=padding-top: 35px> Sphere Y is now moved away from X, as in Figure (b). <strong>Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). Sphere Y is now moved away from X, as in Figure (b). What are the final charge states of X and Y?</strong> A) Both X and Y are neutral. B) X is positive and Y is neutral. C) X is neutral and Y is positive. D) X is negative and Y is positive. E) Both X and Y are negative. <div style=padding-top: 35px> What are the final charge states of X and Y?

A) Both X and Y are neutral.
B) X is positive and Y is neutral.
C) X is neutral and Y is positive.
D) X is negative and Y is positive.
E) Both X and Y are negative.
Question
Electric field of multiple point-charges: The figure shows two unequal point charges, q and Q, of opposite sign. Charge Q has greater magnitude than charge q. In which of the regions X, Y, Z will there be a point at which the net electric field due to these two charges is zero? <strong>Electric field of multiple point-charges: The figure shows two unequal point charges, q and Q, of opposite sign. Charge Q has greater magnitude than charge q. In which of the regions X, Y, Z will there be a point at which the net electric field due to these two charges is zero? </strong> A) only regions X and Z B) only region X C) only region Y D) only region Z E) all three regions <div style=padding-top: 35px>

A) only regions X and Z
B) only region X
C) only region Y
D) only region Z
E) all three regions
Question
Coulomb's law: Three point charges are placed on the x-axis. A charge of +2.0 μC is placed at the origin, -2.0 μC to the right at x = 50 cm, and +4.0 μC at the 100 cm mark. What are the magnitude and direction of the electrostatic force that acts on the charge at the origin? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
Question
Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as

A) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . <div style=padding-top: 35px> .
B) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . <div style=padding-top: 35px> .
C) - <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . <div style=padding-top: 35px> .
D) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . <div style=padding-top: 35px> .
E) - <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . <div style=padding-top: 35px> .
Question
Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?

A) F/3
B) F/ <strong>Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?</strong> A) F/3 B) F/ C) F D) F E) 3F <div style=padding-top: 35px>
C) F
D) <strong>Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?</strong> A) F/3 B) F/ C) F D) F E) 3F <div style=padding-top: 35px> F
E) 3F
Question
Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to

A) 2d.
B) <strong>Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to</strong> A) 2d. B) d. C) d/ . D) d/2. E) d/4. <div style=padding-top: 35px> d.
C) d/ <strong>Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to</strong> A) 2d. B) d. C) d/ . D) d/2. E) d/4. <div style=padding-top: 35px> .
D) d/2.
E) d/4.
Question
Parallel plates: Two very large parallel sheets a distance d apart have their centers directly opposite each other. The sheets carry equal but opposite uniform surface charge densities. A point charge that is placed near the middle of the sheets a distance d/2 from each of them feels an electrical force F due to the sheets. If this charge is now moved closer to one of the sheets so that it is a distance d/4 from that sheet, what force will feel?

A) 4F
B) 2F
C) F
D) F/2
E) F/4
Question
Coulomb's law: Two identical small conducting spheres are separated by 0.60 m. The spheres carry different amounts of charge and each sphere experiences an attractive electric force of 10.8 N. The total charge on the two spheres is -24 μC. The two spheres are now connected by a slender conducting wire, which is then removed. The electric force on each sphere is closest to

A) zero.
B) 3.6 N, attractive.
C) 5.4 N, attractive.
D) 3.6 N, repulsive.
E) 5.4 N, repulsive.
Question
Electric field of multiple point-charges: Two point charges Q1 and Q2 of equal magnitudes and opposite signs are positioned as shown in the figure. Which of the arrows best represents the net electric field at point P due to these two charges? <strong>Electric field of multiple point-charges: Two point charges Q<sub>1</sub> and Q<sub>2</sub> of equal magnitudes and opposite signs are positioned as shown in the figure. Which of the arrows best represents the net electric field at point P due to these two charges? </strong> A) A B) B C) C D) D E) The field is equal to zero at point P. <div style=padding-top: 35px>

A) A
B) B
C) C
D) D
E) The field is equal to zero at point P.
Question
Coulomb's law: When two point charges are 2.0 cm apart, each one experiences a 1.0-N electric force due to the other charge. If they are moved to a new separation of 8.0 cm, the electric force on each of them is closest to

A) 1.0 N.
B) 4.0 N.
C) 16 N.
D) 0.25 N.
E) 0.063 N.
Question
Coulomb's law: A positive point charge Q is fixed on a very large horizontal frictionless tabletop. A second positive point charge q is released from rest near the stationary charge and is free to move. Which statement best describes the motion of q after it is released?

A) Its speed will be greatest just after it is released.
B) Its acceleration is zero just after it is released.
C) As it moves farther and farther from Q, its acceleration will keep increasing.
D) As it moves farther and farther from Q, its speed will decrease.
E) As it moves farther and farther from Q, its speed will keep increasing.
Question
Coulomb's law: Two identical small charged spheres are a certain distance apart, and each one initially experiences an electrostatic force of magnitude F due to the other. With time, charge gradually leaks off of both spheres. When each of the spheres has lost half its initial charge, the magnitude of the electrostatic force will be

A) 1/16 F.
B) 1/8 F.
C) 1/4 F.
D) 1/2 F.
Question
Electric field of a single point-charge: A metal sphere of radius 10 cm carries a charge of +2.0 μC uniformly distributed over its surface. What is the magnitude of the electric field due to this sphere at a point 5.0 cm outside the sphere's surface? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 4.0 × 105 N/C
B) 8.0 × 105 N/C
C) 4.2 × 106 N/C
D) 4.0 × 107 N/C
E) 8.0 × 107 N/C
Question
Electric field of a single point-charge: A small glass bead has been charged to 8.0 nC. What is the magnitude of the electric field 2.0 cm from the center of the bead? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 1.8 × 105 N/C
B) 3.6 × 103 N/C
C) 1.4 × 10-3 N/C
D) 3.6 × 10-6 N/C
Question
Multiple point-charges: A point charge Q = -500 nC and two unknown point charges, q1 and q2, are placed as shown in the figure. The electric field at the origin O, due to charges Q, q1 and q2, is equal to zero. The charge q1 is closest to <strong>Multiple point-charges: A point charge Q = -500 nC and two unknown point charges, q<sub>1</sub> and q<sub>2</sub>, are placed as shown in the figure. The electric field at the origin O, due to charges Q, q<sub>1</sub> and q<sub>2</sub>, is equal to zero. The charge q<sub>1</sub> is closest to </strong> A) 130 nC. B) 76 nC. C) 150 nC. D) -76 nC. E) -130 nC. <div style=padding-top: 35px>

A) 130 nC.
B) 76 nC.
C) 150 nC.
D) -76 nC.
E) -130 nC.
Question
Coulomb's law: In the figure, charge Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? <div style=padding-top: 35px> = 3.1 × Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? <div style=padding-top: 35px> C is placed at the origin and charge Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? <div style=padding-top: 35px> is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? <div style=padding-top: 35px>
Question
Multiple point-charges: Two point charges, Q1 = -1.0 μC and Q2 = + 4.0 μC, are placed as shown in the figure. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) The y component of the electric field, at the origin O, is closest to <strong>Multiple point-charges: Two point charges, Q<sub>1 </sub>= -1.0 μC and Q<sub>2 </sub>= + 4.0 μC, are placed as shown in the figure. (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) The y component of the electric field, at the origin O, is closest to </strong> A) 6.0 × 10<sup>-3</sup> N/C. B) -6.0 × 10<sup>-3</sup> N/C. C) 3.8 × 10<sup>-3</sup> N/C. D) -3.8 × 10<sup>-3</sup> N/C. E) 7.1 × 10<sup>-3</sup> N/C. <div style=padding-top: 35px>

A) 6.0 × 10-3 N/C.
B) -6.0 × 10-3 N/C.
C) 3.8 × 10-3 N/C.
D) -3.8 × 10-3 N/C.
E) 7.1 × 10-3 N/C.
Question
Charge in an electric field: A point charge Q of mass 8.50 g hangs from the horizontal ceiling by a light 25.0-cm thread. When a horizontal electric field of magnitude 1750 N/C is turned on, the charge hangs away from the vertical as shown in the figure. The magnitude of Q is closest to <strong>Charge in an electric field: A point charge Q of mass 8.50 g hangs from the horizontal ceiling by a light 25.0-cm thread. When a horizontal electric field of magnitude 1750 N/C is turned on, the charge hangs away from the vertical as shown in the figure. The magnitude of Q is closest to </strong> A) 27.5 µC. B) 47.6 µC. C) 55.0 µC. D) 3.0 µC. E) 3.5 µC. <div style=padding-top: 35px>

A) 27.5 µC.
B) 47.6 µC.
C) 55.0 µC.
D) 3.0 µC.
E) 3.5 µC.
Question
Coulomb's law: A + 7.00 μC point charge and - 9.00 μC point charge are placed along the x-axis at x = 0.000 cm and x = 40.0 cm, respectively. Where must a third charge, q, be placed along the x-axis so that it does not experience any net electric force due to the other two charges?

A) -0.200 m
B) 2.99 m
C) - 0.187 m
D) - 2.99 m
E) 0.187 m
Question
Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C <strong>Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 , what is the charge that it carries?</strong> A) 1.15 C B) -1.15 C C) 1150 C D) -1150 C <div style=padding-top: 35px> . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 <strong>Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 , what is the charge that it carries?</strong> A) 1.15 C B) -1.15 C C) 1150 C D) -1150 C <div style=padding-top: 35px> , what is the charge that it carries?

A) 1.15 C
B) -1.15 C
C) 1150 C
D) -1150 C
Question
Coulomb's law: The point charge at the bottom of the figure is Q = + 17 nC, and the curve is a circular arc. What is the magnitude of the force on the charge Q due to the other point charges shown? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: The point charge at the bottom of the figure is Q = + 17 nC, and the curve is a circular arc. What is the magnitude of the force on the charge Q due to the other point charges shown? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 1.9 × 10<sup>-4</sup> N B) 1.2 × 10<sup>-4</sup> N C) 1.6 × 10<sup>-4</sup> N D) 2.3 × 10<sup>-4</sup> N <div style=padding-top: 35px>

A) 1.9 × 10-4 N
B) 1.2 × 10-4 N
C) 1.6 × 10-4 N
D) 2.3 × 10-4 N
Question
Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge <div style=padding-top: 35px> N/C directed toward the negative charge
B) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge <div style=padding-top: 35px> N/C directed toward the positive charge
C) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge <div style=padding-top: 35px> N/C directed toward the negative charge
D) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge <div style=padding-top: 35px> N/C directed toward the positive charge
E) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge <div style=padding-top: 35px> N/C directed toward the negative charge
Question
Coulomb's law: In the figure Q = 5.8 nC and all other quantities are accurate to 2 significant figures. What is the magnitude of the force on the charge Q? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: In the figure Q = 5.8 nC and all other quantities are accurate to 2 significant figures. What is the magnitude of the force on the charge Q? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 1.8 × 10<sup>-3</sup> N B) 1.0 × 10<sup>-3</sup> N C) 9.0 × 10<sup>-4</sup> N D) 1.2 × 10<sup>-3</sup> N <div style=padding-top: 35px>

A) 1.8 × 10-3 N
B) 1.0 × 10-3 N
C) 9.0 × 10-4 N
D) 1.2 × 10-3 N
Question
Coulomb's law: In the figure, a small spherical insulator of mass 6.00 × 10-2 kg and charge +0.400 μC is hung by a thin wire of negligible mass. A charge of -0.220 μC is held 0.290 m away from the sphere and directly to the right of it, so the wire makes an angle θ with the vertical, as shown. What is the angle θ? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: In the figure, a small spherical insulator of mass 6.00 × 10<sup>-2</sup> kg and charge +0.400 μC is hung by a thin wire of negligible mass. A charge of -0.220 μC is held 0.290 m away from the sphere and directly to the right of it, so the wire makes an angle θ with the vertical, as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 0.917° B) 1.10° C) 1.30° D) 1.50° E) 1.70° <div style=padding-top: 35px>

A) 0.917°
B) 1.10°
C) 1.30°
D) 1.50°
E) 1.70°
Question
Electric field of a single point-charge: An atomic nucleus has a charge of +40e. What is the magnitude of the electric field at a distance of 1.0 m from the center of the nucleus? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2, e = 1.60 × 10-19C)

A) 5.4 × 10-8 N/C
B) 5.6 × 10-8 N/C
C) 5.8 × 10-8 N/C
D) 6.0 × 10-8 N/C
Question
Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (mproton = 1.67 × 10-27 kg, e = 1.60 × 10-19C)

A) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> opposite to the electric field
B) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> opposite to the electric field
C) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> in the direction of the electric field
D) 67.1 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field <div style=padding-top: 35px> opposite to the electric field
Question
Multiple point-charges: Three +3.0-μC point charges are at the three corners of a square of side 0.50 m. The last corner is occupied by a -3.0-μC charge. Find the magnitude of the electric field at the center of the square. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
Question
Electric field of a single point-charge: The electric field 1.5 cm from a very small charged object points toward the object with a magnitude of 180,000 N/C. What is the charge on the object? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) - 4.5 nC
B) + 4.5 nC
C) - 5.0 nC
D) + 5.0 nC
Question
Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is <strong>Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is For what charge q<sub>1</sub> will charge q<sub>2</sub> be in static equilibrium? </strong> A) 12 nC B) 6.2 nC C) 3.1 nC D) 25 nC <div style=padding-top: 35px> For what charge q1 will charge q2 be in static equilibrium? <strong>Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is For what charge q<sub>1</sub> will charge q<sub>2</sub> be in static equilibrium? </strong> A) 12 nC B) 6.2 nC C) 3.1 nC D) 25 nC <div style=padding-top: 35px>

A) 12 nC
B) 6.2 nC
C) 3.1 nC
D) 25 nC
Question
Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to <strong>Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to and hang at rest as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 4.1° B) 8.2° C) 12° D) 16° <div style=padding-top: 35px> and hang at rest as shown. What is the angle θ? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to and hang at rest as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 4.1° B) 8.2° C) 12° D) 16° <div style=padding-top: 35px>

A) 4.1°
B) 8.2°
C) 12°
D) 16°
Question
Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass <strong>Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass that has been charged to </strong> A) 2.1 × 10<sup>7</sup> N/C B) 2.4 × 10<sup>6</sup> N/C C) 4.5 × 10<sup>6</sup> N/C D) 6.4 × 10<sup>6</sup> N/C <div style=padding-top: 35px> that has been charged to <strong>Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass that has been charged to </strong> A) 2.1 × 10<sup>7</sup> N/C B) 2.4 × 10<sup>6</sup> N/C C) 4.5 × 10<sup>6</sup> N/C D) 6.4 × 10<sup>6</sup> N/C <div style=padding-top: 35px>

A) 2.1 × 107 N/C
B) 2.4 × 106 N/C
C) 4.5 × 106 N/C
D) 6.4 × 106 N/C
Question
Coulomb's law: Two small insulating spheres are attached to silk threads and aligned vertically as shown in the figure. These spheres have equal masses of 40 g, and carry charges q1 and q2 of equal magnitude 2.0 μC but opposite sign. The spheres are brought into the positions shown in the figure, with a vertical separation of 15 cm between them. Note that you cannot neglect gravity. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) The tension in the lower thread is closest to <strong>Coulomb's law: Two small insulating spheres are attached to silk threads and aligned vertically as shown in the figure. These spheres have equal masses of 40 g, and carry charges q<sub>1</sub> and q<sub>2</sub> of equal magnitude 2.0 μC but opposite sign.<sup> </sup>The spheres are brought into the positions shown in the figure, with a vertical separation of 15 cm between them. Note that you cannot neglect gravity. (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) The tension in the lower thread is closest to </strong> A) 1.2 N. B) 1.4 N. C) 1.6 N. D) 1.8 N. E) 2.0 N. <div style=padding-top: 35px>

A) 1.2 N.
B) 1.4 N.
C) 1.6 N.
D) 1.8 N.
E) 2.0 N.
Question
Charged disk: A thin, circular disk of radius 30.0 cm is oriented in the yz-plane with its center at the origin. The disk carries a total charge of +3.00 μC distributed uniformly over its surface. Calculate the magnitude of the electric field due to the disk at the point x = 15.0 cm along the x-axis. (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 9.95 × 105 N/C
B) 4.98 × 105 N/C
C) 3.31 × 105 N/C
D) 2.49 × 105 N/C
E) 1.99 × 105 N/C
Question
Dipoles: A dipole with a positive charge of <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> and a negative charge of <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 0.56 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> N/C
B) -0.56 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> N/C
C) 0.28 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> N/C
D) -0.28 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <div style=padding-top: 35px> N/C
Question
Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of vo = 2.0 × 107 m/s, as shown in the figure. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) The velocity of the electron as it strikes plate B is closest to <strong>Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of v<sub>o</sub> = 2.0 × 10<sup>7 </sup>m/s, as shown in the figure. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) The velocity of the electron as it strikes plate B is closest to </strong> A) 1.2 × 10<sup>7</sup> m/s. B) 1.5 × 10<sup>7</sup> m/s. C) 1.8 × 10<sup>7</sup> m/s. D) 2.1 × 10<sup>7</sup> m/s. E) 2.4 × 10<sup>7</sup> m/s. <div style=padding-top: 35px>

A) 1.2 × 107 m/s.
B) 1.5 × 107 m/s.
C) 1.8 × 107 m/s.
D) 2.1 × 107 m/s.
E) 2.4 × 107 m/s.
Question
Finite line of charge: Two thin 80.0-cm rods are oriented at right angles to each other. Each rod has one end at the origin of the coordinates, and one of them extends along the +x-axis while the other extends along the +y-axis. The rod along the +x-axis carries a charge of -15.0 µC distributed uniformly along its length, and the other rod carries +15.0 µC uniformly over its length. Find the magnitude and direction of the net electrical force that these two rods exert on an electron located at the point (40.0 cm, 40.0 cm). (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2)
Question
Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field <strong>Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field = (3.0 × 10<sup>6</sup> N/C) to bring the dipole to its stable equilibrium position?</strong> A) 0.060 J B) 0.030 J C) 0.00 J D) 0.020 J E) 0.12 J <div style=padding-top: 35px> = (3.0 × 106 N/C) <strong>Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field = (3.0 × 10<sup>6</sup> N/C) to bring the dipole to its stable equilibrium position?</strong> A) 0.060 J B) 0.030 J C) 0.00 J D) 0.020 J E) 0.12 J <div style=padding-top: 35px> to bring the dipole to its stable equilibrium position?

A) 0.060 J
B) 0.030 J
C) 0.00 J
D) 0.020 J
E) 0.12 J
Question
Infinite line of charge: A very long wire carries a uniform linear charge density of <strong>Infinite line of charge: A very long wire carries a uniform linear charge density of What is the electric field strength from the center of the wire at a point on the wire's perpendicular bisector? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2/</sup>N ∙ m<sup>2</sup>)</strong> A) 7.9 N/C B) 3.9 N/C C) 0.49 N/C D) 0.031 N/C <div style=padding-top: 35px> What is the electric field strength <strong>Infinite line of charge: A very long wire carries a uniform linear charge density of What is the electric field strength from the center of the wire at a point on the wire's perpendicular bisector? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2/</sup>N ∙ m<sup>2</sup>)</strong> A) 7.9 N/C B) 3.9 N/C C) 0.49 N/C D) 0.031 N/C <div style=padding-top: 35px> from the center of the wire at a point on the wire's perpendicular bisector? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 7.9 N/C
B) 3.9 N/C
C) 0.49 N/C
D) 0.031 N/C
Question
Infinite line of charge: At a distance of 4.3 cm from the center of a very long uniformly charged wire, the electric field has magnitude 2000 N/C and is directed toward the wire. What is the charge on a 1.0 cm length of wire near the center? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) - 0.048 nC
B) - 0.052 nC
C) - 0.044 nC
D) - 0.056 nC
Question
Parallel plates: Two flat 4.0 cm × 4.0 cm electrodes carrying equal but opposite charges are spaced 2.0 mm apart with their midpoints opposite each other. Between the electrodes but not near their edges, the electric field strength is 2.5 × 106 N/C. What is the magnitude of the charge on each electrode? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 35 nC
B) 18 nC
C) 16 nC
D) 30 nC
Question
Parallel plates: The electric field strength in the space between two closely spaced parallel disks is 1.0 × 105 N/C. This field is the result of transferring 3.9 × 109 electrons from one disk to the other. What is the diameter of the disks? (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 3.0 cm
B) 1.5 cm
C) 4.5 cm
D) 6.0 cm
Question
Multiple point-charges: A 5.0-μC point charge is placed at the 0.00 cm mark of a meter stick and a -4.0-μC point charge is placed at the 50 cm mark. At what point on a line joining the two charges is the electric field due to these charges equal to zero?
Question
Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) (-3.6 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero <div style=padding-top: 35px>
B) (1.8 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero <div style=padding-top: 35px>
C) (-1.8 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero <div style=padding-top: 35px>
D) (3.6 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero <div style=padding-top: 35px>
E) zero
Question
Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) <div style=padding-top: 35px> The electrical field due to the plates has magnitude Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) <div style=padding-top: 35px> between the plates away from the edges. If the plates are Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) <div style=padding-top: 35px> long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) <div style=padding-top: 35px>
Question
Dipoles: An electric dipole consists of charges ±5.00 µC separated by 1.20 mm. It is placed in a vertical electric field of magnitude 525 N/C oriented as shown in the figure. The magnitude of the net torque this field exerts on the dipole is closest to <strong>Dipoles: An electric dipole consists of charges ±5.00 µC separated by 1.20 mm. It is placed in a vertical electric field of magnitude 525 N/C oriented as shown in the figure. The magnitude of the net torque this field exerts on the dipole is closest to </strong> A) 2.02 × 10<sup>-6</sup> N ∙ m. B) 3.15 × 10<sup>-6</sup> N ∙ m. C) 2.41 × 10<sup>-6</sup> N ∙ m. D) 1.01 × 10<sup>-6</sup> N ∙ m. E) 1.21 × 10<sup>-6</sup> N ∙ m. <div style=padding-top: 35px>

A) 2.02 × 10-6 N ∙ m.
B) 3.15 × 10-6 N ∙ m.
C) 2.41 × 10-6 N ∙ m.
D) 1.01 × 10-6 N ∙ m.
E) 1.21 × 10-6 N ∙ m.
Question
Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m2. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m2. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) (+1.13 × 105 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C) <div style=padding-top: 35px>
B) (-2.83 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C) <div style=padding-top: 35px>
C) (+1.19 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C) <div style=padding-top: 35px>
D) (+1.69 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C) <div style=padding-top: 35px>
E) (-1.19 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C) <div style=padding-top: 35px>
Question
Parallel plates: An electric field is set up between two parallel plates, each of area 2.0 m2, by putting 1.0 μC of charge on one plate and -1.0 μC of charge on the other. The plates are separated by 4.0 mm with their centers opposite each other, and the charges are distributed uniformly over the surface of the plates. What is the magnitude of the electric field between the plates at a distance of 1.0 mm from the positive plate, but not near the edges of the plates? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 4.2 × 104 N/C
B) 1.4 × 104 N/C
C) 3.1 × 104 N/C
D) 0.00 N/C
E) 5.6 × 104 N/C
Question
Charged ring: In the figure, a ring 0.71 m in radius carries a charge of + 580 nC uniformly distributed over it. A point charge Q is placed at the center of the ring. The electric field is equal to zero at field point P, which is on the axis of the ring, and 0.73 m from its center. (ε0 = 8.85 × 10-12 C2/N ∙ m2) The point charge Q is closest to <strong>Charged ring: In the figure, a ring 0.71 m in radius carries a charge of + 580 nC uniformly distributed over it. A point charge Q is placed at the center of the ring. The electric field is equal to zero at field point P, which is on the axis of the ring, and 0.73 m from its center. (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>) The point charge Q is closest to </strong> A) -210. B) -300. C) -420. D) 210. E) 300. <div style=padding-top: 35px>

A) -210.
B) -300.
C) -420.
D) 210.
E) 300.
Question
Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of vo = 1.0 × 107 m/s, as shown in the figure. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) The distance of closest approach of the electron to plate B is nearest to <strong>Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of v<sub>o</sub> = 1.0 × 10<sup>7 </sup>m/s, as shown in the figure. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) The distance of closest approach of the electron to plate B is nearest to </strong> A) 16 mm. B) 18 mm. C) 20 mm. D) 22 mm. E) 24 mm. <div style=padding-top: 35px>

A) 16 mm.
B) 18 mm.
C) 20 mm.
D) 22 mm.
E) 24 mm.
Question
Multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d. What is the magnitude of the net electric field at the center of the square? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
Question
Dipoles: An initially-stationary electric dipole of dipole moment <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m <div style=padding-top: 35px> = (5.00 × 10-10 C ∙ m) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m <div style=padding-top: 35px> placed in an electric field <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m <div style=padding-top: 35px> = (2.00 × 106 N/C) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m <div style=padding-top: 35px> + (2.00 × 106 N/C) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m <div style=padding-top: 35px> . What is the magnitude of the maximum torque that the electric field exerts on the dipole?

A) 2.00 × 10-3 N ∙ m
B) 1.40 × 10-3 N ∙ m
C) 2.80 × 10-3 N ∙ m
D) 0.00 N ∙ m
E) 1.00 × 10-3 N ∙ m
Question
Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m <div style=padding-top: 35px> positive point charge is located at <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m <div style=padding-top: 35px> <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m <div style=padding-top: 35px> Find the coordinates of the point where the net electric field strength due to these charges is zero.

A) x = 0.00 m, y = 0.55 m
B) x = 0.00 m, y = 0.67 m
C) x = 0.00 m, y = 1.5 m
D) x = 0.00 m, y = 0.60 m
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Deck 17: Temperature and Heat
1
Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become <strong>Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become </strong> A) d. B) 2d. C) 4d. D) 8d.

A) <strong>Coulomb's law: One very small uniformly charged plastic ball is located directly above another such charge in a test tube as shown in the figure. The balls are in equilibrium a distance d apart. If the charge on each ball is doubled, the distance between the balls in the test tube would become </strong> A) d. B) 2d. C) 4d. D) 8d. d.
B) 2d.
C) 4d.
D) 8d.
2d.
2
Coulomb's law: A 1.0-C point charge is 15 m from a second point charge, and the electric force on one of them due to the other is 1.0 N. What is the magnitude of the second charge? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 25 C
B) 1.0 C
C) 10 nC
D) 0.025 C
E) 25 nC
25 nC
3
Electric field of multiple point-charges: The figure shows three electric charges labeled Q1, Q2, Q3, and some electric field lines in the region surrounding the charges. What are the signs of the three charges? <strong>Electric field of multiple point-charges: The figure shows three electric charges labeled Q<sub>1</sub>, Q<sub>2</sub>, Q<sub>3</sub>, and some electric field lines in the region surrounding the charges. What are the signs of the three charges? </strong> A) Q<sub>1</sub> is positive, Q<sub>2</sub> is negative, Q<sub>3</sub> is positive. B) Q<sub>1</sub> is negative, Q<sub>2</sub> is positive, Q<sub>3</sub> is negative. C) Q<sub>1</sub> is positive, Q<sub>2</sub> is positive, Q<sub>3</sub> is negative. D) All three charges are negative. E) All three charges are positive.

A) Q1 is positive, Q2 is negative, Q3 is positive.
B) Q1 is negative, Q2 is positive, Q3 is negative.
C) Q1 is positive, Q2 is positive, Q3 is negative.
D) All three charges are negative.
E) All three charges are positive.
Q1 is positive, Q2 is negative, Q3 is positive.
4
Charge: A piece of plastic has a net charge of +2.00 μC. How many more protons than electrons does this piece of plastic have? (e = 1.60 × 10-19C)

A) 1.25 × 1013
B) 1.25 × 1019
C) 2.50 × 1013
D) 2.50 × 1019
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5
Motion of a charged particle: An electron is initially moving to the right when it enters a uniform electric field directed upwards. Which trajectory shown below will the electron follow? <strong>Motion of a charged particle: An electron is initially moving to the right when it enters a uniform electric field directed upwards. Which trajectory shown below will the electron follow? </strong> A) trajectory W B) trajectory X C) trajectory Y D) trajectory Z

A) trajectory W
B) trajectory X
C) trajectory Y
D) trajectory Z
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6
Parallel plates: Two large, flat, horizontally oriented plates are parallel to each other, a distance d apart. Half way between the two plates the electric field has magnitude E. If the separation of the plates is reduced to d/2 what is the magnitude of the electric field half way between the plates?

A) 4E
B) 2E
C) E
D) 0
E) E/2
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7
Coulomb's law: Charge Q1 = 6.0 nC is at (0.30 m, 0), charge Q2 = -1.0 nC is at (0, 0.10 m), and charge Q3 = 5.0 nC is at (0, 0). What are the magnitude and direction of the net electrostatic force on the 5.0-nC charge due to the other charges? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
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8
Electric field of multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d as shown in the figure. Which of the arrows represents the direction of the net electric field at the center of the square? <strong>Electric field of multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d as shown in the figure. Which of the arrows represents the direction of the net electric field at the center of the square? </strong> A) A B) B C) C D) D E) The field is equal to zero at point P.

A) A
B) B
C) C
D) D
E) The field is equal to zero at point P.
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9
Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). <strong>Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). Sphere Y is now moved away from X, as in Figure (b). What are the final charge states of X and Y?</strong> A) Both X and Y are neutral. B) X is positive and Y is neutral. C) X is neutral and Y is positive. D) X is negative and Y is positive. E) Both X and Y are negative. Sphere Y is now moved away from X, as in Figure (b). <strong>Induction: X and Y are two uncharged metal spheres on insulating stands, and are in contact with each other. A positively charged rod R is brought close to X as shown in Figure (a). Sphere Y is now moved away from X, as in Figure (b). What are the final charge states of X and Y?</strong> A) Both X and Y are neutral. B) X is positive and Y is neutral. C) X is neutral and Y is positive. D) X is negative and Y is positive. E) Both X and Y are negative. What are the final charge states of X and Y?

A) Both X and Y are neutral.
B) X is positive and Y is neutral.
C) X is neutral and Y is positive.
D) X is negative and Y is positive.
E) Both X and Y are negative.
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10
Electric field of multiple point-charges: The figure shows two unequal point charges, q and Q, of opposite sign. Charge Q has greater magnitude than charge q. In which of the regions X, Y, Z will there be a point at which the net electric field due to these two charges is zero? <strong>Electric field of multiple point-charges: The figure shows two unequal point charges, q and Q, of opposite sign. Charge Q has greater magnitude than charge q. In which of the regions X, Y, Z will there be a point at which the net electric field due to these two charges is zero? </strong> A) only regions X and Z B) only region X C) only region Y D) only region Z E) all three regions

A) only regions X and Z
B) only region X
C) only region Y
D) only region Z
E) all three regions
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11
Coulomb's law: Three point charges are placed on the x-axis. A charge of +2.0 μC is placed at the origin, -2.0 μC to the right at x = 50 cm, and +4.0 μC at the 100 cm mark. What are the magnitude and direction of the electrostatic force that acts on the charge at the origin? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
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12
Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as

A) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . .
B) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . .
C) - <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . .
D) <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . .
E) - <strong>Electric field of multiple point-charges: Four equal negative point charges are located at the corners of a square, their positions in the xy-plane being (1, 1), (-1, 1), (-1, -1), (1, -1). The electric field on the x-axis at (1, 0) points in the same direction as</strong> A) . B) . C) - . D) . E) - . .
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13
Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?

A) F/3
B) F/ <strong>Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?</strong> A) F/3 B) F/ C) F D) F E) 3F
C) F
D) <strong>Coulomb's law: A point charge Q is located a short distance from a point charge 3Q, and no other charges are present. If the electrical force on Q is F, what is the electrical force on 3Q?</strong> A) F/3 B) F/ C) F D) F E) 3F F
E) 3F
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14
Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to

A) 2d.
B) <strong>Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to</strong> A) 2d. B) d. C) d/ . D) d/2. E) d/4. d.
C) d/ <strong>Coulomb's law: When two point charges are a distance d part, the electric force that each one feels from the other has magnitude F. In order to make this force twice as strong, the distance would have to be changed to</strong> A) 2d. B) d. C) d/ . D) d/2. E) d/4. .
D) d/2.
E) d/4.
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15
Parallel plates: Two very large parallel sheets a distance d apart have their centers directly opposite each other. The sheets carry equal but opposite uniform surface charge densities. A point charge that is placed near the middle of the sheets a distance d/2 from each of them feels an electrical force F due to the sheets. If this charge is now moved closer to one of the sheets so that it is a distance d/4 from that sheet, what force will feel?

A) 4F
B) 2F
C) F
D) F/2
E) F/4
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16
Coulomb's law: Two identical small conducting spheres are separated by 0.60 m. The spheres carry different amounts of charge and each sphere experiences an attractive electric force of 10.8 N. The total charge on the two spheres is -24 μC. The two spheres are now connected by a slender conducting wire, which is then removed. The electric force on each sphere is closest to

A) zero.
B) 3.6 N, attractive.
C) 5.4 N, attractive.
D) 3.6 N, repulsive.
E) 5.4 N, repulsive.
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17
Electric field of multiple point-charges: Two point charges Q1 and Q2 of equal magnitudes and opposite signs are positioned as shown in the figure. Which of the arrows best represents the net electric field at point P due to these two charges? <strong>Electric field of multiple point-charges: Two point charges Q<sub>1</sub> and Q<sub>2</sub> of equal magnitudes and opposite signs are positioned as shown in the figure. Which of the arrows best represents the net electric field at point P due to these two charges? </strong> A) A B) B C) C D) D E) The field is equal to zero at point P.

A) A
B) B
C) C
D) D
E) The field is equal to zero at point P.
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18
Coulomb's law: When two point charges are 2.0 cm apart, each one experiences a 1.0-N electric force due to the other charge. If they are moved to a new separation of 8.0 cm, the electric force on each of them is closest to

A) 1.0 N.
B) 4.0 N.
C) 16 N.
D) 0.25 N.
E) 0.063 N.
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19
Coulomb's law: A positive point charge Q is fixed on a very large horizontal frictionless tabletop. A second positive point charge q is released from rest near the stationary charge and is free to move. Which statement best describes the motion of q after it is released?

A) Its speed will be greatest just after it is released.
B) Its acceleration is zero just after it is released.
C) As it moves farther and farther from Q, its acceleration will keep increasing.
D) As it moves farther and farther from Q, its speed will decrease.
E) As it moves farther and farther from Q, its speed will keep increasing.
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20
Coulomb's law: Two identical small charged spheres are a certain distance apart, and each one initially experiences an electrostatic force of magnitude F due to the other. With time, charge gradually leaks off of both spheres. When each of the spheres has lost half its initial charge, the magnitude of the electrostatic force will be

A) 1/16 F.
B) 1/8 F.
C) 1/4 F.
D) 1/2 F.
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21
Electric field of a single point-charge: A metal sphere of radius 10 cm carries a charge of +2.0 μC uniformly distributed over its surface. What is the magnitude of the electric field due to this sphere at a point 5.0 cm outside the sphere's surface? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 4.0 × 105 N/C
B) 8.0 × 105 N/C
C) 4.2 × 106 N/C
D) 4.0 × 107 N/C
E) 8.0 × 107 N/C
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22
Electric field of a single point-charge: A small glass bead has been charged to 8.0 nC. What is the magnitude of the electric field 2.0 cm from the center of the bead? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 1.8 × 105 N/C
B) 3.6 × 103 N/C
C) 1.4 × 10-3 N/C
D) 3.6 × 10-6 N/C
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23
Multiple point-charges: A point charge Q = -500 nC and two unknown point charges, q1 and q2, are placed as shown in the figure. The electric field at the origin O, due to charges Q, q1 and q2, is equal to zero. The charge q1 is closest to <strong>Multiple point-charges: A point charge Q = -500 nC and two unknown point charges, q<sub>1</sub> and q<sub>2</sub>, are placed as shown in the figure. The electric field at the origin O, due to charges Q, q<sub>1</sub> and q<sub>2</sub>, is equal to zero. The charge q<sub>1</sub> is closest to </strong> A) 130 nC. B) 76 nC. C) 150 nC. D) -76 nC. E) -130 nC.

A) 130 nC.
B) 76 nC.
C) 150 nC.
D) -76 nC.
E) -130 nC.
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24
Coulomb's law: In the figure, charge Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? = 3.1 × Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? C is placed at the origin and charge Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero? Coulomb's law: In the figure, charge = 3.1 × C is placed at the origin and charge is placed on the x-axis, at x = -0.20 m. Where along the x-axis can a third charge Q = -8.3 µC be placed such that the resultant force on this third charge is zero?
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25
Multiple point-charges: Two point charges, Q1 = -1.0 μC and Q2 = + 4.0 μC, are placed as shown in the figure. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) The y component of the electric field, at the origin O, is closest to <strong>Multiple point-charges: Two point charges, Q<sub>1 </sub>= -1.0 μC and Q<sub>2 </sub>= + 4.0 μC, are placed as shown in the figure. (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) The y component of the electric field, at the origin O, is closest to </strong> A) 6.0 × 10<sup>-3</sup> N/C. B) -6.0 × 10<sup>-3</sup> N/C. C) 3.8 × 10<sup>-3</sup> N/C. D) -3.8 × 10<sup>-3</sup> N/C. E) 7.1 × 10<sup>-3</sup> N/C.

A) 6.0 × 10-3 N/C.
B) -6.0 × 10-3 N/C.
C) 3.8 × 10-3 N/C.
D) -3.8 × 10-3 N/C.
E) 7.1 × 10-3 N/C.
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26
Charge in an electric field: A point charge Q of mass 8.50 g hangs from the horizontal ceiling by a light 25.0-cm thread. When a horizontal electric field of magnitude 1750 N/C is turned on, the charge hangs away from the vertical as shown in the figure. The magnitude of Q is closest to <strong>Charge in an electric field: A point charge Q of mass 8.50 g hangs from the horizontal ceiling by a light 25.0-cm thread. When a horizontal electric field of magnitude 1750 N/C is turned on, the charge hangs away from the vertical as shown in the figure. The magnitude of Q is closest to </strong> A) 27.5 µC. B) 47.6 µC. C) 55.0 µC. D) 3.0 µC. E) 3.5 µC.

A) 27.5 µC.
B) 47.6 µC.
C) 55.0 µC.
D) 3.0 µC.
E) 3.5 µC.
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27
Coulomb's law: A + 7.00 μC point charge and - 9.00 μC point charge are placed along the x-axis at x = 0.000 cm and x = 40.0 cm, respectively. Where must a third charge, q, be placed along the x-axis so that it does not experience any net electric force due to the other two charges?

A) -0.200 m
B) 2.99 m
C) - 0.187 m
D) - 2.99 m
E) 0.187 m
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28
Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C <strong>Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 , what is the charge that it carries?</strong> A) 1.15 C B) -1.15 C C) 1150 C D) -1150 C . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 <strong>Charge in an electric field: A small sphere with a mass of 441 g is moving upward along the vertical +y-axis when it encounters an electric field of 5.00 N/C . If, due to this field, the sphere suddenly acquires a horizontal acceleration of 13.0 m/s2 , what is the charge that it carries?</strong> A) 1.15 C B) -1.15 C C) 1150 C D) -1150 C , what is the charge that it carries?

A) 1.15 C
B) -1.15 C
C) 1150 C
D) -1150 C
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29
Coulomb's law: The point charge at the bottom of the figure is Q = + 17 nC, and the curve is a circular arc. What is the magnitude of the force on the charge Q due to the other point charges shown? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: The point charge at the bottom of the figure is Q = + 17 nC, and the curve is a circular arc. What is the magnitude of the force on the charge Q due to the other point charges shown? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 1.9 × 10<sup>-4</sup> N B) 1.2 × 10<sup>-4</sup> N C) 1.6 × 10<sup>-4</sup> N D) 2.3 × 10<sup>-4</sup> N

A) 1.9 × 10-4 N
B) 1.2 × 10-4 N
C) 1.6 × 10-4 N
D) 2.3 × 10-4 N
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30
Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge N/C directed toward the negative charge
B) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge N/C directed toward the positive charge
C) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge N/C directed toward the negative charge
D) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge N/C directed toward the positive charge
E) 25.2 × <strong>Multiple point-charges: Two point charges of + 20.0 μC and - 8.00 μC are separated by a distance of 20.0 cm. What is the magnitude of electric field due to these charges at a point midway between them? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 25.2 × N/C directed toward the negative charge B) 25.2 × N/C directed toward the positive charge C) 25.2 × N/C directed toward the negative charge D) 25.2 × N/C directed toward the positive charge E) 25.2 × N/C directed toward the negative charge N/C directed toward the negative charge
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31
Coulomb's law: In the figure Q = 5.8 nC and all other quantities are accurate to 2 significant figures. What is the magnitude of the force on the charge Q? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: In the figure Q = 5.8 nC and all other quantities are accurate to 2 significant figures. What is the magnitude of the force on the charge Q? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 1.8 × 10<sup>-3</sup> N B) 1.0 × 10<sup>-3</sup> N C) 9.0 × 10<sup>-4</sup> N D) 1.2 × 10<sup>-3</sup> N

A) 1.8 × 10-3 N
B) 1.0 × 10-3 N
C) 9.0 × 10-4 N
D) 1.2 × 10-3 N
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32
Coulomb's law: In the figure, a small spherical insulator of mass 6.00 × 10-2 kg and charge +0.400 μC is hung by a thin wire of negligible mass. A charge of -0.220 μC is held 0.290 m away from the sphere and directly to the right of it, so the wire makes an angle θ with the vertical, as shown. What is the angle θ? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: In the figure, a small spherical insulator of mass 6.00 × 10<sup>-2</sup> kg and charge +0.400 μC is hung by a thin wire of negligible mass. A charge of -0.220 μC is held 0.290 m away from the sphere and directly to the right of it, so the wire makes an angle θ with the vertical, as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 0.917° B) 1.10° C) 1.30° D) 1.50° E) 1.70°

A) 0.917°
B) 1.10°
C) 1.30°
D) 1.50°
E) 1.70°
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33
Electric field of a single point-charge: An atomic nucleus has a charge of +40e. What is the magnitude of the electric field at a distance of 1.0 m from the center of the nucleus? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2, e = 1.60 × 10-19C)

A) 5.4 × 10-8 N/C
B) 5.6 × 10-8 N/C
C) 5.8 × 10-8 N/C
D) 6.0 × 10-8 N/C
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34
Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (mproton = 1.67 × 10-27 kg, e = 1.60 × 10-19C)

A) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field opposite to the electric field
B) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field opposite to the electric field
C) 6.71 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field in the direction of the electric field
D) 67.1 × <strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field m/
<strong>Charge in an electric field: A proton is placed in an electric field of intensity 700 N/C. What are the magnitude and direction of the acceleration of this proton due to this field? (m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg, e = 1.60 × 10<sup>-19</sup>C)</strong> A) 6.71 × m/ opposite to the electric field B) 6.71 × m/ opposite to the electric field C) 6.71 × m/ in the direction of the electric field D) 67.1 × m/ opposite to the electric field opposite to the electric field
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35
Multiple point-charges: Three +3.0-μC point charges are at the three corners of a square of side 0.50 m. The last corner is occupied by a -3.0-μC charge. Find the magnitude of the electric field at the center of the square. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
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36
Electric field of a single point-charge: The electric field 1.5 cm from a very small charged object points toward the object with a magnitude of 180,000 N/C. What is the charge on the object? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) - 4.5 nC
B) + 4.5 nC
C) - 5.0 nC
D) + 5.0 nC
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37
Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is <strong>Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is For what charge q<sub>1</sub> will charge q<sub>2</sub> be in static equilibrium? </strong> A) 12 nC B) 6.2 nC C) 3.1 nC D) 25 nC For what charge q1 will charge q2 be in static equilibrium? <strong>Coulomb's law: In the figure, all the charges are point charges and the charge in the middle is For what charge q<sub>1</sub> will charge q<sub>2</sub> be in static equilibrium? </strong> A) 12 nC B) 6.2 nC C) 3.1 nC D) 25 nC

A) 12 nC
B) 6.2 nC
C) 3.1 nC
D) 25 nC
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38
Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to <strong>Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to and hang at rest as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 4.1° B) 8.2° C) 12° D) 16° and hang at rest as shown. What is the angle θ? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) <strong>Coulomb's law: The figure shows two tiny 5.0-g spheres suspended from two very thin 1.0-m-long threads. The spheres repel each other after being charged to and hang at rest as shown. What is the angle θ? (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) </strong> A) 4.1° B) 8.2° C) 12° D) 16°

A) 4.1°
B) 8.2°
C) 12°
D) 16°
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39
Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass <strong>Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass that has been charged to </strong> A) 2.1 × 10<sup>7</sup> N/C B) 2.4 × 10<sup>6</sup> N/C C) 4.5 × 10<sup>6</sup> N/C D) 6.4 × 10<sup>6</sup> N/C that has been charged to <strong>Charge in an electric field: What is the minimum magnitude of an electric field that balances the weight of a plastic sphere of mass that has been charged to </strong> A) 2.1 × 10<sup>7</sup> N/C B) 2.4 × 10<sup>6</sup> N/C C) 4.5 × 10<sup>6</sup> N/C D) 6.4 × 10<sup>6</sup> N/C

A) 2.1 × 107 N/C
B) 2.4 × 106 N/C
C) 4.5 × 106 N/C
D) 6.4 × 106 N/C
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40
Coulomb's law: Two small insulating spheres are attached to silk threads and aligned vertically as shown in the figure. These spheres have equal masses of 40 g, and carry charges q1 and q2 of equal magnitude 2.0 μC but opposite sign. The spheres are brought into the positions shown in the figure, with a vertical separation of 15 cm between them. Note that you cannot neglect gravity. (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2) The tension in the lower thread is closest to <strong>Coulomb's law: Two small insulating spheres are attached to silk threads and aligned vertically as shown in the figure. These spheres have equal masses of 40 g, and carry charges q<sub>1</sub> and q<sub>2</sub> of equal magnitude 2.0 μC but opposite sign.<sup> </sup>The spheres are brought into the positions shown in the figure, with a vertical separation of 15 cm between them. Note that you cannot neglect gravity. (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>) The tension in the lower thread is closest to </strong> A) 1.2 N. B) 1.4 N. C) 1.6 N. D) 1.8 N. E) 2.0 N.

A) 1.2 N.
B) 1.4 N.
C) 1.6 N.
D) 1.8 N.
E) 2.0 N.
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41
Charged disk: A thin, circular disk of radius 30.0 cm is oriented in the yz-plane with its center at the origin. The disk carries a total charge of +3.00 μC distributed uniformly over its surface. Calculate the magnitude of the electric field due to the disk at the point x = 15.0 cm along the x-axis. (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 9.95 × 105 N/C
B) 4.98 × 105 N/C
C) 3.31 × 105 N/C
D) 2.49 × 105 N/C
E) 1.99 × 105 N/C
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42
Dipoles: A dipole with a positive charge of <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C and a negative charge of <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)

A) 0.56 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C N/C
B) -0.56 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C N/C
C) 0.28 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C N/C
D) -0.28 <strong>Dipoles: A dipole with a positive charge of and a negative charge of is centered at the origin and oriented along the x-axis with the positive charge located to the right of the origin. The charge separation is 0.0010 m. Find the electric field due to this dipole at the point (k = 1/4πε<sub>0</sub> = 8.99 × 10<sup>9</sup> N ∙ m<sup>2</sup>/C<sup>2</sup>)</strong> A) 0.56 N/C B) -0.56 N/C C) 0.28 N/C D) -0.28 N/C N/C
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43
Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of vo = 2.0 × 107 m/s, as shown in the figure. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) The velocity of the electron as it strikes plate B is closest to <strong>Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of v<sub>o</sub> = 2.0 × 10<sup>7 </sup>m/s, as shown in the figure. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) The velocity of the electron as it strikes plate B is closest to </strong> A) 1.2 × 10<sup>7</sup> m/s. B) 1.5 × 10<sup>7</sup> m/s. C) 1.8 × 10<sup>7</sup> m/s. D) 2.1 × 10<sup>7</sup> m/s. E) 2.4 × 10<sup>7</sup> m/s.

A) 1.2 × 107 m/s.
B) 1.5 × 107 m/s.
C) 1.8 × 107 m/s.
D) 2.1 × 107 m/s.
E) 2.4 × 107 m/s.
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44
Finite line of charge: Two thin 80.0-cm rods are oriented at right angles to each other. Each rod has one end at the origin of the coordinates, and one of them extends along the +x-axis while the other extends along the +y-axis. The rod along the +x-axis carries a charge of -15.0 µC distributed uniformly along its length, and the other rod carries +15.0 µC uniformly over its length. Find the magnitude and direction of the net electrical force that these two rods exert on an electron located at the point (40.0 cm, 40.0 cm). (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2)
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45
Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field <strong>Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field = (3.0 × 10<sup>6</sup> N/C) to bring the dipole to its stable equilibrium position?</strong> A) 0.060 J B) 0.030 J C) 0.00 J D) 0.020 J E) 0.12 J = (3.0 × 106 N/C) <strong>Dipoles: An electric dipole is made of two charges of equal magnitudes and opposite signs. The positive charge, q = 1.0 μC, is located at the point (x, y, z) = (0.00 cm, 1.0 cm, 0.00 cm), while the negative charge is located at the point (x, y, z) = (0.00 cm, -1.0 cm, 0.00 cm). How much work will be done by an electric field = (3.0 × 10<sup>6</sup> N/C) to bring the dipole to its stable equilibrium position?</strong> A) 0.060 J B) 0.030 J C) 0.00 J D) 0.020 J E) 0.12 J to bring the dipole to its stable equilibrium position?

A) 0.060 J
B) 0.030 J
C) 0.00 J
D) 0.020 J
E) 0.12 J
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46
Infinite line of charge: A very long wire carries a uniform linear charge density of <strong>Infinite line of charge: A very long wire carries a uniform linear charge density of What is the electric field strength from the center of the wire at a point on the wire's perpendicular bisector? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2/</sup>N ∙ m<sup>2</sup>)</strong> A) 7.9 N/C B) 3.9 N/C C) 0.49 N/C D) 0.031 N/C What is the electric field strength <strong>Infinite line of charge: A very long wire carries a uniform linear charge density of What is the electric field strength from the center of the wire at a point on the wire's perpendicular bisector? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2/</sup>N ∙ m<sup>2</sup>)</strong> A) 7.9 N/C B) 3.9 N/C C) 0.49 N/C D) 0.031 N/C from the center of the wire at a point on the wire's perpendicular bisector? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 7.9 N/C
B) 3.9 N/C
C) 0.49 N/C
D) 0.031 N/C
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47
Infinite line of charge: At a distance of 4.3 cm from the center of a very long uniformly charged wire, the electric field has magnitude 2000 N/C and is directed toward the wire. What is the charge on a 1.0 cm length of wire near the center? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) - 0.048 nC
B) - 0.052 nC
C) - 0.044 nC
D) - 0.056 nC
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48
Parallel plates: Two flat 4.0 cm × 4.0 cm electrodes carrying equal but opposite charges are spaced 2.0 mm apart with their midpoints opposite each other. Between the electrodes but not near their edges, the electric field strength is 2.5 × 106 N/C. What is the magnitude of the charge on each electrode? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 35 nC
B) 18 nC
C) 16 nC
D) 30 nC
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49
Parallel plates: The electric field strength in the space between two closely spaced parallel disks is 1.0 × 105 N/C. This field is the result of transferring 3.9 × 109 electrons from one disk to the other. What is the diameter of the disks? (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 3.0 cm
B) 1.5 cm
C) 4.5 cm
D) 6.0 cm
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50
Multiple point-charges: A 5.0-μC point charge is placed at the 0.00 cm mark of a meter stick and a -4.0-μC point charge is placed at the 50 cm mark. At what point on a line joining the two charges is the electric field due to these charges equal to zero?
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51
Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) (-3.6 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero
B) (1.8 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero
C) (-1.8 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero
D) (3.6 × 103 N/C) <strong>Infinite line of charge: A long, thin rod parallel to the y-axis is located at x = -1.0 cm and carries a uniform linear charge density of +1.0 nC/m. A second long, thin rod parallel to the z-axis is located at x = +1.0 cm and carries a uniform linear charge density of -1.0 nC/m. What is the net electric field due to these rods at the origin? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (-3.6 × 10<sup>3</sup> N/C) B) (1.8 × 10<sup>3</sup> N/C) C) (-1.8 × 10<sup>3</sup> N/C) D) (3.6 × 10<sup>3</sup> N/C) E) zero
E) zero
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52
Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) The electrical field due to the plates has magnitude Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) between the plates away from the edges. If the plates are Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) Motion of a charged particle: In the figure, a proton is projected horizontally midway between two parallel plates that are separated by The electrical field due to the plates has magnitude between the plates away from the edges. If the plates are long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)
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53
Dipoles: An electric dipole consists of charges ±5.00 µC separated by 1.20 mm. It is placed in a vertical electric field of magnitude 525 N/C oriented as shown in the figure. The magnitude of the net torque this field exerts on the dipole is closest to <strong>Dipoles: An electric dipole consists of charges ±5.00 µC separated by 1.20 mm. It is placed in a vertical electric field of magnitude 525 N/C oriented as shown in the figure. The magnitude of the net torque this field exerts on the dipole is closest to </strong> A) 2.02 × 10<sup>-6</sup> N ∙ m. B) 3.15 × 10<sup>-6</sup> N ∙ m. C) 2.41 × 10<sup>-6</sup> N ∙ m. D) 1.01 × 10<sup>-6</sup> N ∙ m. E) 1.21 × 10<sup>-6</sup> N ∙ m.

A) 2.02 × 10-6 N ∙ m.
B) 3.15 × 10-6 N ∙ m.
C) 2.41 × 10-6 N ∙ m.
D) 1.01 × 10-6 N ∙ m.
E) 1.21 × 10-6 N ∙ m.
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54
Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m2. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m2. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) (+1.13 × 105 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C)
B) (-2.83 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C)
C) (+1.19 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C)
D) (+1.69 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C)
E) (-1.19 × 10 N/C) <strong>Parallel plates: Two very large, flat plates are parallel to each other. Plate A, located at y = 1.0 cm, is along the xz-plane and carries a uniform surface charge density -1.00 μC/m<sup>2</sup>. Plate B is located at y = -1.0 cm and carries a uniform surface charge density +2.00 μC/m<sup>2</sup>. What is the electric field vector at the point having x, y, z coordinates (-0.50 cm, 0.00 cm, 0.00 cm)? (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>)</strong> A) (+1.13 × 10<sup>5</sup> N/C) B) (-2.83 × 10 N/C) C) (+1.19 × 10 N/C) D) (+1.69 × 10 N/C) E) (-1.19 × 10 N/C)
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55
Parallel plates: An electric field is set up between two parallel plates, each of area 2.0 m2, by putting 1.0 μC of charge on one plate and -1.0 μC of charge on the other. The plates are separated by 4.0 mm with their centers opposite each other, and the charges are distributed uniformly over the surface of the plates. What is the magnitude of the electric field between the plates at a distance of 1.0 mm from the positive plate, but not near the edges of the plates? (ε0 = 8.85 × 10-12 C2/N ∙ m2)

A) 4.2 × 104 N/C
B) 1.4 × 104 N/C
C) 3.1 × 104 N/C
D) 0.00 N/C
E) 5.6 × 104 N/C
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56
Charged ring: In the figure, a ring 0.71 m in radius carries a charge of + 580 nC uniformly distributed over it. A point charge Q is placed at the center of the ring. The electric field is equal to zero at field point P, which is on the axis of the ring, and 0.73 m from its center. (ε0 = 8.85 × 10-12 C2/N ∙ m2) The point charge Q is closest to <strong>Charged ring: In the figure, a ring 0.71 m in radius carries a charge of + 580 nC uniformly distributed over it. A point charge Q is placed at the center of the ring. The electric field is equal to zero at field point P, which is on the axis of the ring, and 0.73 m from its center. (ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>) The point charge Q is closest to </strong> A) -210. B) -300. C) -420. D) 210. E) 300.

A) -210.
B) -300.
C) -420.
D) 210.
E) 300.
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57
Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of vo = 1.0 × 107 m/s, as shown in the figure. (e = 1.60 × 10-19 C, ε0 = 8.85 × 10-12 C2/N ∙ m2, mel = 9.11 × 10-31 kg) The distance of closest approach of the electron to plate B is nearest to <strong>Motion of a charged particle: A pair of charged conducting plates produces a uniform field of 12,000 N/C, directed to the right, between the plates. The separation of the plates is 40 mm. An electron is projected from plate A, directly toward plate B, with an initial velocity of v<sub>o</sub> = 1.0 × 10<sup>7 </sup>m/s, as shown in the figure. (e<sub> </sub>= 1.60 × 10<sup>-19 </sup>C, ε<sub>0</sub> = 8.85 × 10<sup>-12</sup> C<sup>2</sup>/N ∙ m<sup>2</sup>, m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) The distance of closest approach of the electron to plate B is nearest to </strong> A) 16 mm. B) 18 mm. C) 20 mm. D) 22 mm. E) 24 mm.

A) 16 mm.
B) 18 mm.
C) 20 mm.
D) 22 mm.
E) 24 mm.
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58
Multiple point-charges: Three equal negative point charges are placed at three of the corners of a square of side d. What is the magnitude of the net electric field at the center of the square? (k = 1/4πε0 = 8.99 × 109 N ∙ m2/C2)
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59
Dipoles: An initially-stationary electric dipole of dipole moment <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m = (5.00 × 10-10 C ∙ m) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m placed in an electric field <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m = (2.00 × 106 N/C) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m + (2.00 × 106 N/C) <strong>Dipoles: An initially-stationary electric dipole of dipole moment = (5.00 × 10<sup>-10</sup> C ∙ m) placed in an electric field = (2.00 × 106 N/C) + (2.00 × 106 N/C) . What is the magnitude of the maximum torque that the electric field exerts on the dipole?</strong> A) 2.00 × 10<sup>-3</sup> N ∙ m B) 1.40 × 10<sup>-3</sup> N ∙ m C) 2.80 × 10<sup>-3</sup> N ∙ m D) 0.00 N ∙ m E) 1.00 × 10<sup>-3</sup> N ∙ m . What is the magnitude of the maximum torque that the electric field exerts on the dipole?

A) 2.00 × 10-3 N ∙ m
B) 1.40 × 10-3 N ∙ m
C) 2.80 × 10-3 N ∙ m
D) 0.00 N ∙ m
E) 1.00 × 10-3 N ∙ m
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60
Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m positive point charge is located at <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m <strong>Multiple point-charges: A 3.0-μC positive point charge is located at the origin and a positive point charge is located at Find the coordinates of the point where the net electric field strength due to these charges is zero.</strong> A) x = 0.00 m, y = 0.55 m B) x = 0.00 m, y = 0.67 m C) x = 0.00 m, y = 1.5 m D) x = 0.00 m, y = 0.60 m Find the coordinates of the point where the net electric field strength due to these charges is zero.

A) x = 0.00 m, y = 0.55 m
B) x = 0.00 m, y = 0.67 m
C) x = 0.00 m, y = 1.5 m
D) x = 0.00 m, y = 0.60 m
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