CBSE • NEET • IIT JEE • JEE Advanced • IB • IGCSE • ICSE • A-Level
Torque on a Current Carrying Loop in a Magnetic Field
A complete premium Physics study page by Kumar Sir covering force couple, magnetic dipole moment, angle relation, stable and unstable equilibrium, moving coil galvanometer, graphs, derivations and exam-level questions.torque on current loop in magnetic field
Phone / WhatsApp: +91-9958461445 | Email: kumarsirphysics@gmail.com | Website: kumarphysicsclasses.com
1. Introduction
When a current carrying rectangular loop is placed in a uniform magnetic field, equal and opposite magnetic forces act on opposite sides of the loop. The net force on the loop is zero, but the two forces act along different lines of action. Therefore they form a couple and produce a turning effect called torque.
F = BIL sinφτ = force × perpendicular distancem = NIA2. Rectangular Current Loop Diagram
The rectangular loop has length l, breadth b, area A = l × b, current I, uniform magnetic field B, area vector A, magnetic moment m, angle α between area vector and magnetic field, and angle θ between the plane of the loop and magnetic field.
3. Magnetic Force on Sides of Loop
For a current carrying side of length l placed perpendicular to the magnetic field, the magnetic force is F = BIl. The two opposite active sides experience equal and opposite forces. These forces do not cancel rotationally because they act along different lines of action. They form a couple.
4. Complete Derivation of Torque
Length = l, breadth = b, area A = lb, current I, magnetic field B, number of turns N, angle α between area vector and B.
Uniform magnetic field; rectangular coil; active sides perpendicular to B; wires are rigid and current is steady.
τ = NBIA sinα; also τ = NBIA cosθDo not write τ = NBIA sinθ when θ is angle between plane and field. Use τ = NBIA cosθ.
5. Vector Form of Torque
m = NIAτ = m × Bτ = mB sinα = NBIA sinαThe vector m is along the area vector. Its direction is given by the right-hand thumb rule: curl fingers in the direction of current and the thumb gives the direction of the area vector or magnetic moment.
6. Angle Relation
α is the angle between area vector and magnetic field. θ is the angle between plane of loop and magnetic field. Since the area vector is perpendicular to the plane of the loop, α + θ = 90°. Hence τ = NBIA sinα = NBIA cosθ.
7. Stable and Unstable Equilibrium
α = 0°, U = -mB, τ = 0α = 180°, U = +mB, τ = 0α = 90°, τmax = NBIA8. Potential Energy of Current Loop
The potential energy of a magnetic dipole in a uniform magnetic field is the negative dot product of magnetic moment and magnetic field.
U = -m · BU = -mB cosαU = -NBIA cosαMinimum potential energy occurs at stable equilibrium, and maximum potential energy occurs at unstable equilibrium.
9. Moving Coil Galvanometer Connection
τ = NBIAτ = kφNBIA = kφI = kφ / NBAA radial magnetic field is used so that the plane of the coil remains parallel to the magnetic field and the area vector remains perpendicular to the field. Therefore sinα = 1 and torque remains maximum for all deflections.
10. Applications
11. Common Student Mistakes
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
Correction: Draw B, area vector, current direction and angle definition before substituting formula.
12. Exam Question Bank With Solutions
A. CBSE Board Questions
CBSE Theory Question 1Explain why equal and opposite forces on a current loop can produce torque.
CBSE Theory Question 2Define magnetic dipole moment of a current loop.
CBSE Theory Question 3Derive torque on a current carrying rectangular coil.
CBSE Theory Question 4Explain stable and unstable equilibrium of a current loop.
CBSE Theory Question 5Why is radial magnetic field used in moving coil galvanometer?
CBSE Theory Question 6Explain the relation between angle α and angle θ.
CBSE Theory Question 7Draw torque versus angle graph and explain important points.
CBSE Theory Question 8Draw potential energy versus angle graph and explain minima and maxima.
CBSE Theory Question 9State applications of torque on current loop.
CBSE Theory Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Theory Question 11Explain why equal and opposite forces on a current loop can produce torque.
CBSE Theory Question 12Define magnetic dipole moment of a current loop.
CBSE Theory Question 13Derive torque on a current carrying rectangular coil.
CBSE Theory Question 14Explain stable and unstable equilibrium of a current loop.
CBSE Theory Question 15Why is radial magnetic field used in moving coil galvanometer?
CBSE Theory Question 16Explain the relation between angle α and angle θ.
CBSE Theory Question 17Draw torque versus angle graph and explain important points.
CBSE Theory Question 18Draw potential energy versus angle graph and explain minima and maxima.
CBSE Theory Question 19State applications of torque on current loop.
CBSE Theory Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Theory Question 21Explain why equal and opposite forces on a current loop can produce torque.
CBSE Theory Question 22Define magnetic dipole moment of a current loop.
CBSE Theory Question 23Derive torque on a current carrying rectangular coil.
CBSE Theory Question 24Explain stable and unstable equilibrium of a current loop.
CBSE Theory Question 25Why is radial magnetic field used in moving coil galvanometer?
CBSE Derivation Question 1Explain why equal and opposite forces on a current loop can produce torque.
CBSE Derivation Question 2Define magnetic dipole moment of a current loop.
CBSE Derivation Question 3Derive torque on a current carrying rectangular coil.
CBSE Derivation Question 4Explain stable and unstable equilibrium of a current loop.
CBSE Derivation Question 5Why is radial magnetic field used in moving coil galvanometer?
CBSE Derivation Question 6Explain the relation between angle α and angle θ.
CBSE Derivation Question 7Draw torque versus angle graph and explain important points.
CBSE Derivation Question 8Draw potential energy versus angle graph and explain minima and maxima.
CBSE Derivation Question 9State applications of torque on current loop.
CBSE Derivation Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Derivation Question 11Explain why equal and opposite forces on a current loop can produce torque.
CBSE Derivation Question 12Define magnetic dipole moment of a current loop.
CBSE Derivation Question 13Derive torque on a current carrying rectangular coil.
CBSE Derivation Question 14Explain stable and unstable equilibrium of a current loop.
CBSE Derivation Question 15Why is radial magnetic field used in moving coil galvanometer?
CBSE Derivation Question 16Explain the relation between angle α and angle θ.
CBSE Derivation Question 17Draw torque versus angle graph and explain important points.
CBSE Derivation Question 18Draw potential energy versus angle graph and explain minima and maxima.
CBSE Derivation Question 19State applications of torque on current loop.
CBSE Derivation Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Numerical Question 1Explain why equal and opposite forces on a current loop can produce torque.
CBSE Numerical Question 2Define magnetic dipole moment of a current loop.
CBSE Numerical Question 3Derive torque on a current carrying rectangular coil.
CBSE Numerical Question 4Explain stable and unstable equilibrium of a current loop.
CBSE Numerical Question 5Why is radial magnetic field used in moving coil galvanometer?
CBSE Numerical Question 6Explain the relation between angle α and angle θ.
CBSE Numerical Question 7Draw torque versus angle graph and explain important points.
CBSE Numerical Question 8Draw potential energy versus angle graph and explain minima and maxima.
CBSE Numerical Question 9State applications of torque on current loop.
CBSE Numerical Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Numerical Question 11Explain why equal and opposite forces on a current loop can produce torque.
CBSE Numerical Question 12Define magnetic dipole moment of a current loop.
CBSE Numerical Question 13Derive torque on a current carrying rectangular coil.
CBSE Numerical Question 14Explain stable and unstable equilibrium of a current loop.
CBSE Numerical Question 15Why is radial magnetic field used in moving coil galvanometer?
CBSE Numerical Question 16Explain the relation between angle α and angle θ.
CBSE Numerical Question 17Draw torque versus angle graph and explain important points.
CBSE Numerical Question 18Draw potential energy versus angle graph and explain minima and maxima.
CBSE Numerical Question 19State applications of torque on current loop.
CBSE Numerical Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
CBSE Numerical Question 21Explain why equal and opposite forces on a current loop can produce torque.
CBSE Numerical Question 22Define magnetic dipole moment of a current loop.
CBSE Numerical Question 23Derive torque on a current carrying rectangular coil.
CBSE Numerical Question 24Explain stable and unstable equilibrium of a current loop.
CBSE Numerical Question 25Why is radial magnetic field used in moving coil galvanometer?
Case Study 1current loop in uniform magnetic field
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 2electric motor
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 3moving coil galvanometer
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 4magnetic dipole
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 5stable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 6unstable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 7torque-angle graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 8potential-energy graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 9coil with N turns
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 10rectangular loop numerical
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
B. NEET Questions
NEET MCQ 1A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 2If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 3Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 4Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 5Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 6Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 7In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 8If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 9If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 10A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 11A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 12If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 13Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 14Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 15Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 16Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 17In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 18If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 19If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 20A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 21A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 22If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 23Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 24Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 25Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 26Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 27In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 28If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 29If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 30A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 31A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 32If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 33Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 34Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 35Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 36Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 37In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 38If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 39If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 40A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 41A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 42If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 43Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 44Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 45Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 46Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 47In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 48If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 49If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 50A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 51A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 52If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 53Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 54Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 55Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 56Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 57In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 58If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 59If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 60A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 61A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 62If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 63Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 64Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 65Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 66Magnetic dipole moment of a coil is
- NIA
- NBA
- NBI
- IA/N
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 67In radial magnetic field of galvanometer
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 68If current is doubled, torque becomes
- half
- same
- double
- four times
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 69If number of turns and area both double, torque becomes
- 2 times
- 4 times
- 8 times
- same
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 70A loop has zero torque but maximum potential energy when α is
- 0°
- 45°
- 90°
- 180°
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 71A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 72If θ is the angle between plane of coil and magnetic field, torque is
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 73Maximum torque occurs when area vector is
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 74Stable equilibrium of current loop occurs when magnetic moment is
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
NEET MCQ 75Potential energy of current loop is
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Medium
Concept Tested: Torque, magnetic moment and angle relation.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
C. JEE Main Questions
JEE Main MCQ 1Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 2Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 3Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 4In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 5If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 6If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 7A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 8A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 9If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 10Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 11Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 12Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 13Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 14In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 15If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 16If number of turns and area both double, torque becomes A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 17A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 18A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 19If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 20Maximum torque occurs when area vector is A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 21Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=6×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=6×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 22Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=8×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=8×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 23Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=10×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=10×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 24In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=12×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=12×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 25If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=2×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=2×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 26If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=4×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=4×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 27A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=6×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=6×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 28A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=8×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=8×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 29If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=10×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=10×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 30Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=12×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=12×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 31Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=2×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=2×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 32Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=4×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=4×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 33Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=6×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=6×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 34In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=8×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=8×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 35If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=10×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=10×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 36If number of turns and area both double, torque becomes A numerical variation may include N=20, I=4 A, A=12×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=4 A, A=12×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 37A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=1 A, A=2×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=1 A, A=2×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 38A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=2 A, A=4×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=2 A, A=4×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 39If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=3 A, A=6×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=3 A, A=6×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 40Maximum torque occurs when area vector is A numerical variation may include N=60, I=4 A, A=8×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=4 A, A=8×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 41Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=10×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=10×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 42Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=12×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=12×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 43Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=2×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=2×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 44In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=4×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=4×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 45If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=6×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=6×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 46If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=8×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=8×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 47A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=10×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=10×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 48A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=12×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=12×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 49If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=2×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=2×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 50Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=4×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=4×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 51Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=6×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=6×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 52Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=8×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=8×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 53Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=10×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=10×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 54In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=12×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=12×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 55If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=2×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=2×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 56If number of turns and area both double, torque becomes A numerical variation may include N=20, I=4 A, A=4×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=4 A, A=4×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 57A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=1 A, A=6×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=1 A, A=6×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 58A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=2 A, A=8×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=2 A, A=8×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 59If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=3 A, A=10×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=3 A, A=10×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 60Maximum torque occurs when area vector is A numerical variation may include N=60, I=4 A, A=12×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=4 A, A=12×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 61Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 62Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 63Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 64In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 65If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 66If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 67A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 68A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 69If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 70Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 71Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 72Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 73Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 74In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Main MCQ 75If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
D. JEE Advanced Questions
JEE Advanced Single Correct MCQ 1Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 2Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 3Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 4In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 5If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 6If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 7A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 8A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 9If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 10Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 11Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 12Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 13Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 14In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 15If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 16If number of turns and area both double, torque becomes A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 17A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 18A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 19If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 20Maximum torque occurs when area vector is A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 21Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=6×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=6×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 22Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=8×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=8×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 23Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=10×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=10×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 24In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=12×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=12×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 25If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=2×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=2×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 26If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=4×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=4×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 27A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=6×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=6×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 28A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=8×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=8×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 29If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=10×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=10×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Single Correct MCQ 30Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=12×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=12×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 1Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=1 A, A=2×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 2Potential energy of current loop is A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=2 A, A=4×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 3Magnetic dipole moment of a coil is A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=3 A, A=6×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 4In radial magnetic field of galvanometer A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=4 A, A=8×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 5If current is doubled, torque becomes A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=1 A, A=10×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 6If number of turns and area both double, torque becomes A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=2 A, A=12×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 7A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=3 A, A=2×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 8A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=4 A, A=4×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 9If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=1 A, A=6×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 10Maximum torque occurs when area vector is A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=2 A, A=8×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 11Stable equilibrium of current loop occurs when magnetic moment is A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- opposite current
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=3 A, A=10×10⁻³ m² and B=0.1 T.
Detailed Explanation: U = -mB cosα is minimum at α = 0°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 12Potential energy of current loop is A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
- mB cosα
- -mB cosα
- mB sinα
- -mB sinα
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=4 A, A=12×10⁻³ m² and B=0.2 T.
Detailed Explanation: For magnetic dipole, U = -m · B.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 13Magnetic dipole moment of a coil is A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
- NIA
- NBA
- NBI
- IA/N
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=1 A, A=2×10⁻³ m² and B=0.3 T.
Detailed Explanation: m = NIA along area vector.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 14In radial magnetic field of galvanometer A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
- torque is zero
- torque remains maximum
- B is zero
- current is not needed
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=2 A, A=4×10⁻³ m² and B=0.4 T.
Detailed Explanation: The area vector remains perpendicular to B, so sinα = 1.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 15If current is doubled, torque becomes A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
- half
- same
- double
- four times
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=3 A, A=6×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ ∝ I.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 16If number of turns and area both double, torque becomes A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
- 2 times
- 4 times
- 8 times
- same
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=20, I=4 A, A=8×10⁻³ m² and B=0.1 T.
Detailed Explanation: τ ∝ NA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 17A loop has zero torque but maximum potential energy when α is A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
- 0°
- 45°
- 90°
- 180°
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=30, I=1 A, A=10×10⁻³ m² and B=0.2 T.
Detailed Explanation: At α = 180°, τ = 0 and U = +mB.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 18A rectangular coil of N turns and area A carries current I in uniform B. If its area vector makes angle α with B, torque is A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
- NBIA sinα
- NBIA cosα
- NBI/A
- NBA/I
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=40, I=2 A, A=12×10⁻³ m² and B=0.3 T.
Detailed Explanation: Use τ = mB sinα and m = NIA.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 19If θ is the angle between plane of coil and magnetic field, torque is A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
- NBIA sinθ
- NBIA cosθ
- NBIA tanθ
- zero always
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=50, I=3 A, A=2×10⁻³ m² and B=0.4 T.
Detailed Explanation: Since α + θ = 90°, sinα = cosθ.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Multiple Correct MCQ 20Maximum torque occurs when area vector is A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
- parallel to B
- antiparallel to B
- perpendicular to B
- zero
Difficulty: Difficult
Concept Tested: Torque, magnetic moment and angle relation. A numerical variation may include N=60, I=4 A, A=4×10⁻³ m² and B=0.5 T.
Detailed Explanation: τ = NBIA sinα is maximum at α = 90°.
Common Student Mistake: Students often confuse α, the angle with area vector, with θ, the angle with the plane.
JEE Advanced Integer Question 1Explain why equal and opposite forces on a current loop can produce torque.
JEE Advanced Integer Question 2Define magnetic dipole moment of a current loop.
JEE Advanced Integer Question 3Derive torque on a current carrying rectangular coil.
JEE Advanced Integer Question 4Explain stable and unstable equilibrium of a current loop.
JEE Advanced Integer Question 5Why is radial magnetic field used in moving coil galvanometer?
JEE Advanced Integer Question 6Explain the relation between angle α and angle θ.
JEE Advanced Integer Question 7Draw torque versus angle graph and explain important points.
JEE Advanced Integer Question 8Draw potential energy versus angle graph and explain minima and maxima.
JEE Advanced Integer Question 9State applications of torque on current loop.
JEE Advanced Integer Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
JEE Advanced Integer Question 11Explain why equal and opposite forces on a current loop can produce torque.
JEE Advanced Integer Question 12Define magnetic dipole moment of a current loop.
JEE Advanced Integer Question 13Derive torque on a current carrying rectangular coil.
JEE Advanced Integer Question 14Explain stable and unstable equilibrium of a current loop.
JEE Advanced Integer Question 15Why is radial magnetic field used in moving coil galvanometer?
JEE Advanced Matrix Match Question 1Explain why equal and opposite forces on a current loop can produce torque.
JEE Advanced Matrix Match Question 2Define magnetic dipole moment of a current loop.
JEE Advanced Matrix Match Question 3Derive torque on a current carrying rectangular coil.
JEE Advanced Matrix Match Question 4Explain stable and unstable equilibrium of a current loop.
JEE Advanced Matrix Match Question 5Why is radial magnetic field used in moving coil galvanometer?
JEE Advanced Matrix Match Question 6Explain the relation between angle α and angle θ.
JEE Advanced Matrix Match Question 7Draw torque versus angle graph and explain important points.
JEE Advanced Matrix Match Question 8Draw potential energy versus angle graph and explain minima and maxima.
JEE Advanced Matrix Match Question 9State applications of torque on current loop.
JEE Advanced Matrix Match Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
JEE Advanced Paragraph Question 1Explain why equal and opposite forces on a current loop can produce torque.
JEE Advanced Paragraph Question 2Define magnetic dipole moment of a current loop.
JEE Advanced Paragraph Question 3Derive torque on a current carrying rectangular coil.
JEE Advanced Paragraph Question 4Explain stable and unstable equilibrium of a current loop.
JEE Advanced Paragraph Question 5Why is radial magnetic field used in moving coil galvanometer?
JEE Advanced Paragraph Question 6Explain the relation between angle α and angle θ.
JEE Advanced Paragraph Question 7Draw torque versus angle graph and explain important points.
JEE Advanced Paragraph Question 8Draw potential energy versus angle graph and explain minima and maxima.
JEE Advanced Paragraph Question 9State applications of torque on current loop.
JEE Advanced Paragraph Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
E. IB Physics Questions
IB Question 1Explain why equal and opposite forces on a current loop can produce torque.
IB Question 2Define magnetic dipole moment of a current loop.
IB Question 3Derive torque on a current carrying rectangular coil.
IB Question 4Explain stable and unstable equilibrium of a current loop.
IB Question 5Why is radial magnetic field used in moving coil galvanometer?
IB Question 6Explain the relation between angle α and angle θ.
IB Question 7Draw torque versus angle graph and explain important points.
IB Question 8Draw potential energy versus angle graph and explain minima and maxima.
IB Question 9State applications of torque on current loop.
IB Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
IB Question 11Explain why equal and opposite forces on a current loop can produce torque.
IB Question 12Define magnetic dipole moment of a current loop.
IB Question 13Derive torque on a current carrying rectangular coil.
IB Question 14Explain stable and unstable equilibrium of a current loop.
IB Question 15Why is radial magnetic field used in moving coil galvanometer?
IB Question 16Explain the relation between angle α and angle θ.
IB Question 17Draw torque versus angle graph and explain important points.
IB Question 18Draw potential energy versus angle graph and explain minima and maxima.
IB Question 19State applications of torque on current loop.
IB Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
IB Question 21Explain why equal and opposite forces on a current loop can produce torque.
IB Question 22Define magnetic dipole moment of a current loop.
IB Question 23Derive torque on a current carrying rectangular coil.
IB Question 24Explain stable and unstable equilibrium of a current loop.
IB Question 25Why is radial magnetic field used in moving coil galvanometer?
F. ICSE Physics Questions
ICSE Question 1Explain why equal and opposite forces on a current loop can produce torque.
ICSE Question 2Define magnetic dipole moment of a current loop.
ICSE Question 3Derive torque on a current carrying rectangular coil.
ICSE Question 4Explain stable and unstable equilibrium of a current loop.
ICSE Question 5Why is radial magnetic field used in moving coil galvanometer?
ICSE Question 6Explain the relation between angle α and angle θ.
ICSE Question 7Draw torque versus angle graph and explain important points.
ICSE Question 8Draw potential energy versus angle graph and explain minima and maxima.
ICSE Question 9State applications of torque on current loop.
ICSE Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
ICSE Question 11Explain why equal and opposite forces on a current loop can produce torque.
ICSE Question 12Define magnetic dipole moment of a current loop.
ICSE Question 13Derive torque on a current carrying rectangular coil.
ICSE Question 14Explain stable and unstable equilibrium of a current loop.
ICSE Question 15Why is radial magnetic field used in moving coil galvanometer?
ICSE Question 16Explain the relation between angle α and angle θ.
ICSE Question 17Draw torque versus angle graph and explain important points.
ICSE Question 18Draw potential energy versus angle graph and explain minima and maxima.
ICSE Question 19State applications of torque on current loop.
ICSE Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
ICSE Question 21Explain why equal and opposite forces on a current loop can produce torque.
ICSE Question 22Define magnetic dipole moment of a current loop.
ICSE Question 23Derive torque on a current carrying rectangular coil.
ICSE Question 24Explain stable and unstable equilibrium of a current loop.
ICSE Question 25Why is radial magnetic field used in moving coil galvanometer?
G. IGCSE Physics Questions
IGCSE Question 1Explain why equal and opposite forces on a current loop can produce torque.
IGCSE Question 2Define magnetic dipole moment of a current loop.
IGCSE Question 3Derive torque on a current carrying rectangular coil.
IGCSE Question 4Explain stable and unstable equilibrium of a current loop.
IGCSE Question 5Why is radial magnetic field used in moving coil galvanometer?
IGCSE Question 6Explain the relation between angle α and angle θ.
IGCSE Question 7Draw torque versus angle graph and explain important points.
IGCSE Question 8Draw potential energy versus angle graph and explain minima and maxima.
IGCSE Question 9State applications of torque on current loop.
IGCSE Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
IGCSE Question 11Explain why equal and opposite forces on a current loop can produce torque.
IGCSE Question 12Define magnetic dipole moment of a current loop.
IGCSE Question 13Derive torque on a current carrying rectangular coil.
IGCSE Question 14Explain stable and unstable equilibrium of a current loop.
IGCSE Question 15Why is radial magnetic field used in moving coil galvanometer?
IGCSE Question 16Explain the relation between angle α and angle θ.
IGCSE Question 17Draw torque versus angle graph and explain important points.
IGCSE Question 18Draw potential energy versus angle graph and explain minima and maxima.
IGCSE Question 19State applications of torque on current loop.
IGCSE Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
IGCSE Question 21Explain why equal and opposite forces on a current loop can produce torque.
IGCSE Question 22Define magnetic dipole moment of a current loop.
IGCSE Question 23Derive torque on a current carrying rectangular coil.
IGCSE Question 24Explain stable and unstable equilibrium of a current loop.
IGCSE Question 25Why is radial magnetic field used in moving coil galvanometer?
H. British Curriculum / A-Level Physics
A-Level Question 1Explain why equal and opposite forces on a current loop can produce torque.
A-Level Question 2Define magnetic dipole moment of a current loop.
A-Level Question 3Derive torque on a current carrying rectangular coil.
A-Level Question 4Explain stable and unstable equilibrium of a current loop.
A-Level Question 5Why is radial magnetic field used in moving coil galvanometer?
A-Level Question 6Explain the relation between angle α and angle θ.
A-Level Question 7Draw torque versus angle graph and explain important points.
A-Level Question 8Draw potential energy versus angle graph and explain minima and maxima.
A-Level Question 9State applications of torque on current loop.
A-Level Question 10Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
A-Level Question 11Explain why equal and opposite forces on a current loop can produce torque.
A-Level Question 12Define magnetic dipole moment of a current loop.
A-Level Question 13Derive torque on a current carrying rectangular coil.
A-Level Question 14Explain stable and unstable equilibrium of a current loop.
A-Level Question 15Why is radial magnetic field used in moving coil galvanometer?
A-Level Question 16Explain the relation between angle α and angle θ.
A-Level Question 17Draw torque versus angle graph and explain important points.
A-Level Question 18Draw potential energy versus angle graph and explain minima and maxima.
A-Level Question 19State applications of torque on current loop.
A-Level Question 20Explain why net force on a closed loop in uniform magnetic field is zero but net torque may be non-zero.
A-Level Question 21Explain why equal and opposite forces on a current loop can produce torque.
A-Level Question 22Define magnetic dipole moment of a current loop.
A-Level Question 23Derive torque on a current carrying rectangular coil.
A-Level Question 24Explain stable and unstable equilibrium of a current loop.
A-Level Question 25Why is radial magnetic field used in moving coil galvanometer?
13. Case Study Section
Case Study 1current loop in uniform magnetic field
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 2electric motor
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 3moving coil galvanometer
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 4magnetic dipole
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 5stable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 6unstable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 7torque-angle graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 8potential-energy graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 9coil with N turns
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 10rectangular loop numerical
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 11current loop in uniform magnetic field
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 12electric motor
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 13moving coil galvanometer
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 14magnetic dipole
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 15stable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 16unstable equilibrium
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 17torque-angle graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 18potential-energy graph
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 19coil with N turns
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
Case Study 20rectangular loop numerical
Questions: calculate torque, identify equilibrium, compare energy, and predict rotation direction.
Solution: Use m = NIA, τ = mB sinα, U = -mB cosα. Stable equilibrium is α = 0°, unstable equilibrium is α = 180°, and maximum torque occurs at α = 90°.
14. Graphs
The torque graph follows a sine curve. The potential energy graph follows negative cosine behaviour. These graphs are very useful for NEET and JEE conceptual questions.
15. Final Revision Sheet
A = l × bF = BIlτ = NBIA sinατ = NBIA cosθm = NIAτ = m × BU = -mB cosαI = kφ/NBACBSE derivation: force couple method. NEET trap: angle relation. JEE trap: energy and equilibrium analysis. Advanced type: combine torque, potential energy and restoring torque.
Need Personal Help?
If torque on a current carrying loop, magnetic dipole moment, area vector, stable equilibrium, unstable equilibrium, moving coil galvanometer, potential energy, numerical problem, MCQ, case study, or advanced question is not clear, students can directly contact Kumar Sir for one-to-one personalized Physics guidance.
Kumar Sir provides personal doubt-solving, conceptual clarity, derivation practice, numerical problem-solving techniques, and advanced Physics mentoring for CBSE, NEET, IIT JEE, JEE Advanced, IB, AP, IGCSE, ICSE and British Curriculum Physics.
