Electrostatics Study Materials for Competitive Exams

Electrostatics

Capacitance Electric Charges & Fields Electric Potential Gauss Law

Q. A charge of +3μC is placed at the origin. What is the potential at a point 0.3m away?

A. 9000 V
B. 3000 V
C. 10000 V
D. 15000 V

Solution

V = k * q / r = (9 × 10^9 N m²/C²) * (3 × 10^-6 C) / 0.3 m = 9000 V.

Correct Answer: A — 9000 V

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Q. A charge of +3μC is placed in a uniform electric field of strength 1500 N/C. What is the work done in moving the charge 0.2 m in the direction of the field?

A. 90 J
B. 60 J
C. 30 J
D. 45 J

Solution

Work done W = F * d = (E * q) * d = (1500 N/C * 3 × 10^-6 C) * 0.2 m = 0.0009 J = 90 J.

Correct Answer: B — 60 J

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Q. A charge of +4μC is placed at the origin. What is the electric field at a point 2m away on the x-axis?

A. 0 N/C
B. 450 N/C
C. 900 N/C
D. 1800 N/C

Solution

E = k * |q| / r^2 = (9 × 10^9) * 4 × 10^-6 / (2)^2 = 450 N/C.

Correct Answer: C — 900 N/C

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Q. A charge of +5μC is placed at the origin. What is the electric field at a point 2m away along the x-axis?

A. 0 N/C
B. 1125 N/C
C. 2250 N/C
D. 4500 N/C

Solution

E = k * |q| / r² = (9 × 10^9 N m²/C²) * (5 × 10^-6 C) / (2 m)² = 1125 N/C.

Correct Answer: C — 2250 N/C

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Q. A charge of +5μC is placed in an electric field of strength 2000 N/C. What is the force experienced by the charge?

A. 10N
B. 1N
C. 100N
D. 200N

Solution

Force F = qE = (5 × 10^-6 C) * (2000 N/C) = 10 N.

Correct Answer: A — 10N

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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 -2μC is placed in an electric field of 500 N/C. What is the force acting on the charge?

A. -1 N
B. 1 N
C. -0.5 N
D. 0.5 N

Solution

Force F = E * q = 500 N/C * -2 × 10^-6 C = -1 N.

Correct Answer: A — -1 N

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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 charge Q is uniformly distributed over a spherical surface of radius R. What is the electric field at a point outside the sphere at distance r from the center?

A. 0
B. Q/4πε₀r²
C. Q/4πε₀R²
D. Q/4πε₀R

Solution

For points outside the sphere, the electric field behaves as if all the charge were concentrated at the center, so E = Q/4πε₀r².

Correct Answer: B — Q/4πε₀r²

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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 particle moves in a uniform electric field. What is the nature of the force acting on it?

A. Constant
B. Variable
C. Zero
D. Centripetal

Solution

In a uniform electric field, the force acting on a charged particle is constant in magnitude and direction.

Correct Answer: A — Constant

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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 cube encloses a charge Q at its center. What is the electric flux through one face of the cube?

A. Q/ε₀
B. Q/6ε₀
C. Q/3ε₀
D. Zero

Solution

The total flux through the cube is Q/ε₀, and since there are 6 faces, the flux through one face is Q/6ε₀.

Correct Answer: B — Q/6ε₀

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Q. A cube of side length a has a charge Q at one of its corners. What is the electric flux through one face of the cube?

A. Q/(6ε₀)
B. Q/(12ε₀)
C. Q/(8ε₀)
D. Q/(4ε₀)

Solution

The total flux through the cube is Q/ε₀, and since the charge is at one corner, the flux through one face is Q/(12ε₀).

Correct Answer: B — Q/(12ε₀)

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Q. A cube of side length a has a charge Q at one of its corners. What is the total electric flux through the cube?

A. Q/ε₀
B. Q/(6ε₀)
C. Q/(12ε₀)
D. 0

Solution

The charge at one corner contributes 1/8 of its flux to the cube. Thus, total flux = (1/8)Q/ε₀ = Q/(12ε₀).

Correct Answer: C — Q/(12ε₀)

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Q. A cylindrical conductor of radius R carries a uniform charge per unit length λ. What is the electric field at a distance r from the axis of the cylinder (r > R)?

A. 0
B. λ/(2πε₀r)
C. λ/(2πε₀R)
D. λ/(4πε₀r²)

Solution

For a point outside the cylinder, the electric field is given by E = λ/(2πε₀r).

Correct Answer: B — λ/(2πε₀r)

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Q. A cylindrical Gaussian surface encloses a charge Q. If the height of the cylinder is doubled while keeping the radius constant, what happens to the electric flux through the curved surface?

A. It doubles
B. It halves
C. It remains the same
D. It becomes zero

Solution

The electric flux through the curved surface is proportional to the charge enclosed, which remains constant, so the flux through the curved surface doubles if the height is doubled.

Correct Answer: A — It doubles

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Q. A cylindrical Gaussian surface encloses a charge Q. If the radius of the cylinder is doubled, what happens to the electric field at the surface?

A. It doubles
B. It halves
C. It remains the same
D. It becomes zero

Solution

The electric field due to a uniformly charged infinite cylinder depends only on the charge per unit length, not on the radius.

Correct Answer: C — It remains the same

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Q. A cylindrical Gaussian surface encloses a charge Q. If the radius of the cylinder is r and its height is h, what is the electric flux through the curved surface?

A. Q/ε₀
B. Q/(2ε₀)
C. Q/(4ε₀)
D. 0

Solution

The electric flux through the curved surface of a cylinder is given by Φ = Q_enc/ε₀, where Q_enc = Q.

Correct Answer: A — Q/ε₀

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Q. A cylindrical Gaussian surface encloses a long straight wire carrying a current. What is the electric field at a distance r from the wire?

A. 0
B. I/(2πε₀r)
C. λ/(2πε₀r)
D. σ/(2ε₀)

Solution

Gauss's law applies to electric fields, not magnetic fields. The electric field around a current-carrying wire is not defined by Gauss's law.

Correct Answer: A — 0

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Q. A cylindrical Gaussian surface encloses a long straight wire carrying a current. What is the electric field at a point outside the cylinder?

A. Zero
B. Directly proportional to the distance from the wire
C. Inversely proportional to the distance from the wire
D. Constant

Solution

The electric field outside the cylindrical surface is directly proportional to the distance from the wire.

Correct Answer: B — Directly proportional to the distance from the wire

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Q. A cylindrical Gaussian surface of length L and radius R encloses a charge Q uniformly distributed along its length. What is the electric field at a distance R from the axis of the cylinder?

A. Q/(2πε₀R)
B. Q/(4πε₀R²)
C. 0
D. Q/(ε₀L)

Solution

Using Gauss's law, the electric field outside the cylinder is E = Q/(2πε₀R).

Correct Answer: A — Q/(2πε₀R)

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Q. A cylindrical Gaussian surface of length L and radius R encloses a charge Q. What is the electric field E at a distance R from the axis of the cylinder?

A. Q/(2πε₀R)
B. Q/(4πε₀R²)
C. Q/(ε₀L)
D. 0

Solution

Using Gauss's law, the electric field E at a distance R from the axis of a long charged cylinder is E = Q/(2πε₀L) for points outside the cylinder.

Correct Answer: A — Q/(2πε₀R)

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Showing 31 to 60 of 363 (13 Pages)

Electrostatics MCQ & Objective Questions

Electrostatics is a crucial topic in physics that deals with the study of electric charges at rest. Understanding electrostatics is essential for students preparing for school exams and competitive tests, as it forms the foundation for many advanced concepts in physics. Practicing MCQs and objective questions on electrostatics not only enhances conceptual clarity but also boosts your confidence in tackling important questions during exams.

What You Will Practise Here

Fundamental concepts of electric charge and its properties
Understanding Coulomb's Law and its applications
Electric field and electric potential: definitions and calculations
Capacitance and capacitors: types and formulas
Gauss's Law and its significance in electrostatics
Concept of electric dipoles and their behavior in electric fields
Key diagrams and graphical representations related to electrostatics

Exam Relevance

Electrostatics is a significant topic in various exams, including CBSE, State Boards, NEET, and JEE. It frequently appears in the form of conceptual questions, numerical problems, and application-based scenarios. Students can expect to encounter questions that require them to apply Coulomb's Law, calculate electric fields, and analyze capacitor circuits. Familiarity with common question patterns will greatly aid in effective exam preparation.

Common Mistakes Students Make

Confusing the concepts of electric field and electric potential
Misapplying Coulomb's Law in multi-charge systems
Neglecting the direction of electric field lines in problem-solving
Overlooking the significance of units and dimensions in calculations
Failing to understand the behavior of capacitors in series and parallel

FAQs

Question: What is the difference between electric field and electric potential?
Answer: The electric field is a vector quantity that represents the force experienced by a unit positive charge, while electric potential is a scalar quantity that indicates the potential energy per unit charge at a point in an electric field.

Question: How do capacitors store energy?
Answer: Capacitors store energy in the form of an electric field created between their plates when a voltage is applied across them.

Now is the time to strengthen your understanding of electrostatics! Dive into our practice MCQs and test your knowledge on this vital topic. The more you practice, the better prepared you will be for your exams!

Electrostatics

Electrostatics MCQ & Objective Questions

What You Will Practise Here

Exam Relevance

Common Mistakes Students Make

FAQs

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