Major Competitive Exams

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Major Competitive Exams

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Major Competitive Exams MCQ & Objective Questions

Major Competitive Exams play a crucial role in shaping the academic and professional futures of students in India. These exams not only assess knowledge but also test problem-solving skills and time management. Practicing MCQs and objective questions is essential for scoring better, as they help in familiarizing students with the exam format and identifying important questions that frequently appear in tests.

What You Will Practise Here

Key concepts and theories related to major subjects
Important formulas and their applications
Definitions of critical terms and terminologies
Diagrams and illustrations to enhance understanding
Practice questions that mirror actual exam patterns
Strategies for solving objective questions efficiently
Time management techniques for competitive exams

Exam Relevance

The topics covered under Major Competitive Exams are integral to various examinations such as CBSE, State Boards, NEET, and JEE. Students can expect to encounter a mix of conceptual and application-based questions that require a solid understanding of the subjects. Common question patterns include multiple-choice questions that test both knowledge and analytical skills, making it essential to be well-prepared with practice MCQs.

Common Mistakes Students Make

Rushing through questions without reading them carefully
Overlooking the negative marking scheme in MCQs
Confusing similar concepts or terms
Neglecting to review previous years’ question papers
Failing to manage time effectively during the exam

FAQs

Question: How can I improve my performance in Major Competitive Exams?
Answer: Regular practice of MCQs and understanding key concepts will significantly enhance your performance.

Question: What types of questions should I focus on for these exams?
Answer: Concentrate on important Major Competitive Exams questions that frequently appear in past papers and mock tests.

Question: Are there specific strategies for tackling objective questions?
Answer: Yes, practicing under timed conditions and reviewing mistakes can help develop effective strategies.

Start your journey towards success by solving practice MCQs today! Test your understanding and build confidence for your upcoming exams. Remember, consistent practice is the key to mastering Major Competitive Exams!

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Q. A changing magnetic field induces a current in a closed loop. What is this phenomenon called?

A. Electromagnetic induction
B. Magnetic resonance
C. Electrolysis
D. Magnetism

Solution

This phenomenon is known as electromagnetic induction, where a changing magnetic field induces an electromotive force (EMF) in a conductor.

Correct Answer: A — Electromagnetic induction

Q. A changing magnetic field induces an electric field. This phenomenon is described by which of the following laws?

A. Faraday's law of induction
B. Ampere's law
C. Gauss's law
D. Ohm's law

Solution

The phenomenon of a changing magnetic field inducing an electric field is described by Faraday's law of induction.

Correct Answer: A — Faraday's law of induction

Q. A changing magnetic field induces an electric field. This phenomenon is known as?

A. Electromagnetic induction
B. Electrostatics
C. Magnetostatics
D. Electrodynamics

Solution

The phenomenon of a changing magnetic field inducing an electric field is known as electromagnetic induction.

Correct Answer: A — Electromagnetic induction

Q. A charge of +1 μC is placed in an electric field of strength 1000 N/C. What is the force experienced by the charge? (2023)

A. 0.001 N
B. 0.01 N
C. 1 N
D. 10 N

Solution

Force F = qE = (1 × 10^-6 C)(1000 N/C) = 0.001 N.

Correct Answer: B — 0.01 N

Q. A charge of +10 μC is placed in an electric field of 2000 N/C. What is the force experienced by the charge? (2023)

A. 20 N
B. 200 N
C. 2 N
D. 0.2 N

Solution

Force F = qE = (10 × 10^-6 C) * (2000 N/C) = 0.02 N = 20 N.

Correct Answer: A — 20 N

Q. A charge of +10 µC is placed in an electric field of strength 2000 N/C. What is the force acting on the charge? (2023)

A. 20 N
B. 200 N
C. 2 N
D. 0.2 N

Solution

Force F = qE = (10 × 10^-6 C) * (2000 N/C) = 0.02 N = 20 N.

Correct Answer: A — 20 N

Q. A charge of +10μC is placed at the origin. What is the electric potential at a point 2m away from the charge?

A. 4500 V
B. 2250 V
C. 5000 V
D. 1000 V

Solution

V = k * q / r = (9 × 10^9) * (10 × 10^-6) / 2 = 4500 V.

Correct Answer: B — 2250 V

Q. A charge of +10μC is placed in a uniform electric field of 500 N/C. What is the force acting on the charge?

A. 0.5 N
B. 5 N
C. 50 N
D. 500 N

Solution

Force F = qE = (10 × 10^-6 C) * (500 N/C) = 5 N.

Correct Answer: B — 5 N

Q. A charge of +10μC is placed in a uniform electric field of strength 500 N/C. What is the work done in moving the charge 0.1m in the direction of the field?

A. 0.5 J
B. 1 J
C. 2 J
D. 0.1 J

Solution

Work done W = F * d = (E * q) * d = (500 N/C * 10 × 10^-6 C) * 0.1 m = 0.5 J.

Correct Answer: A — 0.5 J

Q. A charge of +10μC is placed in a uniform electric field of strength 500 N/C. What is the work done in moving the charge 2m in the direction of the field?

A. 10 J
B. 1 J
C. 100 J
D. 0.5 J

Solution

Work done W = F * d = (E * q) * d = (500 N/C * 10 × 10^-6 C) * 2m = 0.01 J.

Correct Answer: A — 10 J

Q. A charge of +2μC is placed in an electric field of 1000 N/C. What is the force experienced by the charge? (2000)

A. 2000 N
B. 2 N
C. 0.002 N
D. 1000 N

Solution

The force F on a charge in an electric field is given by F = qE. Here, F = 2 * 10^-6 C * 1000 N/C = 0.002 N.

Correct Answer: A — 2000 N

Q. A charge of +3μC is placed at the origin. What is the electric potential at a point 0.5m away?

A. 5400 V
B. 1800 V
C. 7200 V
D. 3600 V

Solution

V = k * q / r = (9 × 10^9) * (3 × 10^-6) / 0.5 = 54000 V.

Correct Answer: D — 3600 V

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

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

Q. A charge of +4 µC is placed in a uniform electric field of strength 500 N/C. What is the work done in moving the charge 0.2 m in the direction of the field?

A. 400 J
B. 200 J
C. 100 J
D. 50 J

Solution

W = F * d = (E * q) * d = (500 N/C * 4 × 10^-6 C) * 0.2 m = 0.4 J.

Correct Answer: B — 200 J

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

Q. A charge of +5 μC is placed in an electric field of 1000 N/C. What is the work done in moving the charge 0.2 m in the direction of the field? (2022)

A. 1 J
B. 0.1 J
C. 0.5 J
D. 2 J

Solution

Work done W = F * d = (E * q) * d = (1000 N/C * 5 × 10^-6 C) * 0.2 m = 0.1 J.

Correct Answer: B — 0.1 J

Q. A charge of +5 µC is placed in an electric field of 300 N/C. What is the work done in moving the charge 0.2 m in the direction of the field? (2019)

A. 30 J
B. 12 J
C. 6 J
D. 3 J

Solution

Work done W = F * d = (E * q) * d = (300 N/C * 5 × 10^-6 C) * 0.2 m = 0.3 J.

Correct Answer: C — 6 J

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

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

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

Q. A charge of -2 µC is placed in an electric field of 500 N/C. What is the direction of the force acting on the charge? (2023)

A. Towards the positive charge
B. Away from the positive charge
C. No force
D. Depends on the field strength

Solution

The force on a negative charge is in the direction opposite to the electric field, hence towards the positive charge.

Correct Answer: A — Towards the positive charge

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

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

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

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

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

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

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

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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