Electric Potential

Q. A capacitor has a capacitance of 10 μF and is charged to a potential of 50 V. What is the energy stored in the capacitor?

A. 0.025 J
B. 0.05 J
C. 0.1 J
D. 0.5 J

Solution

Energy stored U = 1/2 * C * V² = 1/2 * 10 × 10^-6 F * (50 V)² = 0.0125 J.

Correct Answer: A — 0.025 J

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Q. A capacitor has a capacitance of 5 μF and is charged to a potential of 12 V. What is the energy stored in the capacitor?

A. 0.36 mJ
B. 0.72 mJ
C. 0.12 mJ
D. 0.24 mJ

Solution

Energy U = 1/2 * C * V² = 1/2 * 5 × 10^-6 F * (12 V)² = 0.36 mJ.

Correct Answer: B — 0.72 mJ

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Q. A capacitor is charged to a potential difference of 12 V. If the capacitance is 4 µF, what is the charge stored in the capacitor?

A. 12 µC
B. 24 µC
C. 48 µC
D. 36 µC

Solution

Charge Q is given by Q = CV. Here, Q = 4 µF * 12 V = 48 µC.

Correct Answer: B — 24 µC

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Q. A capacitor is charged to a potential difference of V. What is the energy stored in the capacitor?

A. 1/2 CV²
B. CV
C. V²/C
D. 1/2 QV

Solution

The energy (U) stored in a capacitor is given by U = 1/2 CV², where C is the capacitance and V is the potential difference.

Correct Answer: A — 1/2 CV²

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Q. A capacitor is charged to a potential of 12 V. If the capacitance is 3 µF, what is the energy stored in the capacitor?

A. 0.18 mJ
B. 0.36 mJ
C. 0.54 mJ
D. 0.72 mJ

Solution

Energy stored in a capacitor is given by U = 1/2 CV² = 1/2 * 3 x 10^-6 F * (12 V)² = 0.36 mJ.

Correct Answer: B — 0.36 mJ

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Q. A capacitor is charged to a potential of 12 V. If the capacitance is 4 µF, what is the energy stored in the capacitor?

A. 0.24 mJ
B. 0.48 mJ
C. 0.12 mJ
D. 0.36 mJ

Solution

Energy stored U = 1/2 CV² = 1/2 * 4 x 10^-6 F * (12 V)² = 0.24 mJ.

Correct Answer: B — 0.48 mJ

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Q. A capacitor is charged to a potential of V. If the charge on the capacitor is doubled, what will be the new potential?

A. V
B. 2V
C. V/2
D. 4V

Solution

The potential V across a capacitor is directly proportional to the charge. If the charge is doubled, the potential also doubles.

Correct Answer: B — 2V

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Q. A charge of -2 μC is placed in an electric field of 1000 N/C. What is the potential energy of the charge? (2000)

A. -2000 J
B. 2000 J
C. 0 J
D. -1000 J

Solution

Potential energy U = q * V = -2 × 10^-6 C * 1000 N/C = -0.002 J.

Correct Answer: A — -2000 J

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Q. A charge of -4 μC is placed in an electric field of 200 N/C. What is the potential energy of the charge?

A. -800 μJ
B. 800 μJ
C. 400 μJ
D. 0 μJ

Solution

Potential energy U = q * V = -4 × 10^-6 C * 200 N/C = -800 μJ.

Correct Answer: A — -800 μJ

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Q. A charge of 4 μC is placed at the origin. What is the electric potential at a point 3 m away?

A. 3000 V
B. 1200 V
C. 4000 V
D. None of the above

Solution

V = k * q / r = (9 × 10^9 N m²/C²) * (4 × 10^-6 C) / (3 m) = 1200 V.

Correct Answer: B — 1200 V

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Q. A charge of 4 μC is placed at the origin. What is the electric potential at a point (3, 4) m?

A. 300 V
B. 200 V
C. 100 V
D. 0 V

Solution

Distance r = √(3² + 4²) = 5 m. V = k * q / r = (9 × 10^9) * (4 × 10^-6) / 5 = 720 V.

Correct Answer: B — 200 V

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Q. A charge of 4 μC is placed in an electric field of 1000 N/C. What is the potential energy of the charge?

A. 4 mJ
B. 2 mJ
C. 1 mJ
D. 0.5 mJ

Solution

Potential energy U = q * V, where V = E * d. Assuming d = 1 m, U = 4 × 10^-6 C * 1000 N/C * 1 m = 4 mJ.

Correct Answer: A — 4 mJ

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Q. A charge of 5 μC is placed in an electric field of 2000 N/C. What is the electric potential energy of the charge?

A. 10 mJ
B. 1 mJ
C. 0.5 mJ
D. 2 mJ

Solution

Electric potential energy (U) = Charge × Electric Field = 5 μC × 2000 N/C = 10 mJ.

Correct Answer: A — 10 mJ

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Q. A charge of 5 μC is placed in an electric field of 2000 N/C. What is the potential energy of the charge?

A. 10 mJ
B. 1 mJ
C. 0.5 mJ
D. 2 mJ

Solution

Potential energy (U) = Charge × Electric Field × Distance. Assuming distance = 1 m, U = 5 μC × 2000 N/C = 10 mJ.

Correct Answer: A — 10 mJ

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Q. A charged capacitor has a potential difference of 12 V across its plates. If the capacitance is 4 µF, what is the charge stored in the capacitor?

A. 48 µC
B. 12 µC
C. 3 µC
D. 24 µC

Solution

Charge Q = C × V = 4 µF × 12 V = 48 µC.

Correct Answer: A — 48 µC

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Q. A charged particle moves from a point of higher electric potential to a point of lower electric potential. What happens to its kinetic energy?

A. Increases
B. Decreases
C. Remains constant
D. Cannot be determined

Solution

As the charged particle moves to a lower potential, it loses potential energy, which is converted into kinetic energy, thus increasing its kinetic energy.

Correct Answer: A — Increases

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Q. A charged particle moves from a region of high potential to low potential. What happens to its kinetic energy?

A. It increases
B. It decreases
C. It remains constant
D. It becomes zero

Solution

As the charged particle moves from high potential to low potential, it loses potential energy, which is converted into kinetic energy, thus its kinetic energy increases.

Correct Answer: A — It increases

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Q. A charged sphere has a radius R and a total charge Q. What is the electric potential at a point outside the sphere at a distance r from the center (r > R)?

A. kQ/R
B. kQ/r
C. kQ/(R+r)
D. 0

Solution

For a charged sphere, the electric potential outside the sphere behaves as if all the charge were concentrated at the center, so V = kQ/r.

Correct Answer: B — kQ/r

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Q. A parallel plate capacitor has a potential difference of V across its plates. What is the electric field between the plates?

A. V/d
B. d/V
C. V²/d
D. d²/V

Solution

The electric field E between the plates of a parallel plate capacitor is given by E = V/d, where d is the separation between the plates.

Correct Answer: A — V/d

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Q. A point charge of +5 µC is placed at the origin. What is the electric potential at a point 2 m away from the charge?

A. 1125 V
B. 450 V
C. 225 V
D. 0 V

Solution

The electric potential V at a distance r from a point charge Q is given by V = kQ/r. Here, V = (9 x 10^9 Nm²/C²)(5 x 10^-6 C)/(2 m) = 1125 V.

Correct Answer: A — 1125 V

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Q. A spherical conductor has a charge Q. What is the electric potential inside the conductor?

A. 0
B. Q/(4πε₀r)
C. Q/(4πε₀R)
D. Constant throughout

Solution

The electric potential inside a charged spherical conductor is constant and equal to the potential on its surface, which is Q/(4πε₀R).

Correct Answer: D — Constant throughout

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Q. A spherical conductor has a radius R and carries a charge Q. What is the electric potential on its surface?

A. kQ/R
B. kQ/2R
C. 0
D. kQ/R²

Solution

The electric potential V on the surface of a charged spherical conductor is given by V = kQ/R.

Correct Answer: A — kQ/R

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Q. A uniform electric field of 200 N/C is present. What is the potential difference between two points 3 m apart?

A. 600 V
B. 400 V
C. 200 V
D. 800 V

Solution

The potential difference V = E * d = 200 N/C * 3 m = 600 V.

Correct Answer: A — 600 V

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Q. If the electric potential at a point is 0 V, what can be said about the electric field at that point?

A. It is zero
B. It is positive
C. It is negative
D. It cannot be determined

Solution

The electric field is the negative gradient of the electric potential. If the potential is constant (0 V), the electric field is zero.

Correct Answer: A — It is zero

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Q. If the electric potential at a point is 10 V and the charge at that point is 2 C, what is the electric potential energy?

A. 5 J
B. 10 J
C. 20 J
D. 40 J

Solution

Electric potential energy U is given by U = VQ. Here, U = 10 V * 2 C = 20 J.

Correct Answer: C — 20 J

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Q. If the electric potential at a point is 10 V and the electric field is uniform, what is the work done in moving a charge of 2 C from that point to a point where the potential is 0 V?

A. 20 J
B. 10 J
C. 5 J
D. 0 J

Solution

Work done W = q(V1 - V2) = 2 C (10 V - 0 V) = 20 J.

Correct Answer: A — 20 J

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Q. If the electric potential at a point is 10 V, what is the work done in bringing a charge of 2 C from infinity to that point?

A. 20 J
B. 10 J
C. 5 J
D. 40 J

Solution

Work done = Charge × Potential = 2 C × 10 V = 20 J.

Correct Answer: A — 20 J

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Q. If the electric potential at a point is 100 V and the electric field is 50 N/C, what is the distance from the charge?

A. 2 m
B. 1 m
C. 0.5 m
D. 4 m

Solution

Distance d = V / E = 100 V / 50 N/C = 2 m.

Correct Answer: A — 2 m

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Q. If the electric potential at a point is 100 V, what is the work done in moving a charge of 2 C from infinity to that point?

A. 200 J
B. 100 J
C. 50 J
D. 0 J

Solution

Work done W = q * V = 2 C * 100 V = 200 J.

Correct Answer: A — 200 J

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Q. If the electric potential at a point is 150 V and the electric field is directed towards the point, what can be said about the charge creating the field?

A. It is positive
B. It is negative
C. It is neutral
D. Cannot be determined

Solution

If the electric field is directed towards the point, it indicates that the charge creating the field is negative.

Correct Answer: B — It is negative

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Showing 1 to 30 of 84 (3 Pages)

Electric Potential MCQ & Objective Questions

Understanding electric potential is crucial for students preparing for school and competitive exams. This concept not only forms the foundation of electrostatics but also plays a significant role in various physics problems. Practicing Electric Potential MCQs and objective questions can enhance your problem-solving skills and boost your confidence, ensuring you score better in exams.

What You Will Practise Here

Definition and significance of electric potential
Key formulas related to electric potential and potential energy
Understanding equipotential surfaces and their properties
Calculating electric potential due to point charges and systems of charges
Relationship between electric field and electric potential
Applications of electric potential in real-world scenarios
Diagrams illustrating electric potential concepts

Exam Relevance

The topic of electric potential is frequently tested in CBSE, State Boards, NEET, and JEE exams. Students can expect questions that require them to apply formulas, interpret graphs, and solve numerical problems. Common question patterns include calculating electric potential from given charge distributions and explaining the significance of equipotential surfaces. Mastery of this topic can significantly enhance your performance in both theoretical and practical assessments.

Common Mistakes Students Make

Confusing electric potential with electric field strength
Neglecting the sign of charges when calculating potential
Overlooking the concept of reference points in potential calculations
Misinterpreting equipotential surfaces and their implications

FAQs

Question: What is electric potential?
Answer: Electric potential is the amount of work done per unit charge in bringing a charge from infinity to a point in an electric field.

Question: How is electric potential related to electric field?
Answer: Electric potential is the integral of the electric field over distance, indicating how much potential energy a unit charge would have at a point in the field.

Now is the time to enhance your understanding of electric potential! Dive into our practice MCQs and test your knowledge to excel in your exams. Remember, consistent practice with important Electric Potential questions will pave the way for your success!

Electric Potential

Electric Potential MCQ & Objective Questions

What You Will Practise Here

Exam Relevance

Common Mistakes Students Make

FAQs

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