Moving Charges and Magnetism - JEE Advanced MCQ | Bhotik Academy

Moving Charges and Magnetism

Class 12 Physics | JEE Advanced Level
Q1.
A proton moving with speed 2 × 106 m s−1 enters a uniform magnetic field of 0.5 T at an angle 30° with the field. The radius of the helical path is closest to:
A. 2.1 cm
B. 4.2 cm
C. 1.3 cm
D. 8.4 cm
Answer: A
Only perpendicular velocity causes circular motion. v = v sin30° = 1 × 106 m s−1.
r = mv / qB = (1.67 × 10−27 × 106)/(1.6 × 10−19 × 0.5) ≈ 2.09 × 10−2 m = 2.1 cm.
Q2.
An electron and a proton enter the same uniform magnetic field with equal kinetic energies and perpendicular velocities. The ratio of their circular radii re : rp is:
A. 1 : 1836
B. 1 : √1836
C. √1836 : 1
D. 1836 : 1
Answer: B
For same K and same |q|, r = p/qB = √(2mK)/qB. Hence r ∝ √m. Therefore re/rp = √(me/mp) = 1/√1836.
Q3.
A charged particle moves in a uniform magnetic field with pitch p and radius r. If its speed is doubled keeping the angle with magnetic field unchanged, the new pitch and radius are:
A. p, r
B. 2p, 2r
C. 2p, r
D. p, 2r
Answer: B
r ∝ v and pitch = vT. Since T = 2πm/qB is unchanged and both velocity components double, radius and pitch both double.
Q4.
A particle of charge q and mass m is accelerated through potential V and then enters a magnetic field B normally. Its radius is:
A. √(2qV/m)/B
B. (1/B)√(2mV/q)
C. (1/B)√(2mVq)
D. B√(2mV/q)
Answer: B
qV = ½mv² ⇒ v = √(2qV/m). Radius r = mv/qB = (1/B)√(2mV/q).
Q5.
In a velocity selector, electric field E and magnetic field B are perpendicular. Ions pass undeviated. If both E and B are doubled, selected speed becomes:
A. v/2
B. v
C. 2v
D. 4v
Answer: B
For no deflection, qE = qvB ⇒ v = E/B. Doubling both E and B keeps E/B unchanged.
Q6.
A wire of length l carries current I along +x-axis. Magnetic field is B = B0(ĵ + k̂). Force on wire is:
A. IlB0(ĵ − k̂)
B. IlB0(k̂ − ĵ)
C. IlB0(ĵ + k̂)
D. zero
Answer: B
F = I L × B = I(l î) × B0(ĵ + k̂) = IlB0(k̂ − ĵ).
Q7.
A semicircular wire of radius R carries current I. It is placed in a uniform magnetic field B perpendicular to its plane. The magnitude of force on the curved part is:
A. πIRB
B. 2IRB
C. IRB
D. zero
Answer: B
Net force on any current-carrying wire in uniform B depends on end-to-end displacement. For semicircle, effective length is diameter 2R. Hence F = I(2R)B = 2IRB.
Q8.
A circular loop of radius R carries current I. It is placed in a uniform magnetic field B with its magnetic moment making 60° with B. Torque is:
A. πR²IB/2
B. √3πR²IB/2
C. πRIB
D. zero
Answer: B
τ = MB sinθ = IA B sin60° = IπR²B × √3/2.
Q9.
A moving coil galvanometer has current sensitivity Si. If number of turns and area are both doubled while torsional constant remains same, new current sensitivity is:
A. Si
B. 2Si
C. 4Si
D. Si/4
Answer: C
Current sensitivity θ/I = NBA/k. If N and A are both doubled, sensitivity becomes 4 times.
Q10.
A galvanometer of resistance 20 Ω gives full scale deflection at 2 mA. The shunt required to convert it into an ammeter of range 1 A is approximately:
A. 0.020 Ω
B. 0.040 Ω
C. 0.080 Ω
D. 20 Ω
Answer: B
Voltage across galvanometer at full scale = IgG = 0.002 × 20 = 0.04 V. Shunt current = 1 − 0.002 = 0.998 A. S = 0.04/0.998 ≈ 0.040 Ω.
Q11.
Two long parallel wires carry currents 3 A and 5 A in opposite directions. Distance between them is 20 cm. Force per unit length is:
A. attractive, 1.5 × 10−5 N m−1
B. repulsive, 1.5 × 10−5 N m−1
C. attractive, 3 × 10−5 N m−1
D. repulsive, 3 × 10−5 N m−1
Answer: B
Opposite currents repel. F/L = μ0I1I2/(2πd) = (2 × 10−7 × 15)/0.2 = 1.5 × 10−5 N m−1.
Q12.
Three long parallel wires are placed at the vertices of an equilateral triangle of side a. Equal currents I flow out of the page in all wires. The magnetic force per unit length on one wire has magnitude:
A. μ0I²/(2πa)
B. √3 μ0I²/(2πa)
C. μ0I²/(πa)
D. zero
Answer: B
Each of two forces has magnitude f = μ0I²/(2πa), attractive along sides, angle 60° between them. Resultant = √(f² + f² + 2f²cos60°) = √3 f.
Q13.
Magnetic field at the centre of a circular loop of radius R carrying current I is B. The field at the centre if the loop is reshaped into a square using the same wire and current is:
A. 2√2B/π²
B. 4√2B/π²
C. 8√2B/π²
D. π²B/8√2
Answer: C
Same wire length: 2πR = 4a ⇒ side of square a = πR/2. Field at centre of square = 4 × [μ0I/(4πd)](sin45° + sin45°), where d = a/2. Thus Bs = 2√2 μ0I/(πa) = 4√2 μ0I/(π²R). Since circular loop field B = μ0I/(2R), Bs/B = 8√2/π².
Q14.
A long straight wire carries current I. A point P is at distance a from it. The magnetic field at P is B. If current is doubled and distance is tripled, field becomes:
A. 2B/3
B. 3B/2
C. 6B
D. B/6
Answer: A
For long wire, B ∝ I/r. New B = B × (2/3) = 2B/3.
Q15.
A current I flows through a circular arc of radius R subtending angle 120° at the centre. Magnetic field at centre due to the arc is:
A. μ0I/(6R)
B. μ0I/(3R)
C. μ0I/(2R)
D. μ0I/(12R)
Answer: A
For arc angle θ in radians, B = μ0Iθ/(4πR). Here θ = 120° = 2π/3. Hence B = μ0I/(6R).
Q16.
Two concentric circular coils of radii R and 2R carry currents I and 2I in opposite directions. Magnetic field at common centre is:
A. zero
B. μ0I/(2R)
C. μ0I/R
D. μ0I/(4R)
Answer: A
Field due to smaller coil = μ0I/(2R). Field due to larger coil = μ0(2I)/(2×2R) = μ0I/(2R). Opposite directions, so net field is zero.
Q17.
A solenoid has n turns per unit length and carries current I. A particle of charge q moves along the solenoid axis with speed v. Magnetic force on particle is:
A. qvμ0nI
B. qvμ0nI/2
C. zero
D. depends on radius of solenoid
Answer: C
Inside a long solenoid, B is along its axis. If particle velocity is also along the axis, angle between v and B is zero. Magnetic force qvB sin0° = 0.
Q18.
A charged particle enters a region where E and B are parallel. If initial velocity is perpendicular to both fields, the particle trajectory is generally:
A. circle
B. straight line
C. helix with changing pitch
D. parabola only
Answer: C
Magnetic field gives circular motion perpendicular to B. Electric field parallel to B accelerates particle along B, so parallel velocity changes with time. Hence helix with changing pitch.
Q19.
A rectangular loop of sides a and b carries current I in uniform magnetic field B. The plane of loop is parallel to B. Torque is:
A. IabB
B. zero
C. I(a+b)B
D. 2IabB
Answer: A
Magnetic moment M = IA normal to plane. If plane is parallel to B, normal is perpendicular to B. Thus τ = MB sin90° = IabB.
Q20.
A magnetic dipole of moment M is rotated from stable equilibrium to unstable equilibrium in a uniform magnetic field B. Work done is:
A. MB
B. 2MB
C. MB/2
D. zero
Answer: B
Potential energy U = −MB cosθ. Stable: θ = 0 ⇒ U = −MB. Unstable: θ = π ⇒ U = +MB. Work done = ΔU = 2MB.
Q21.
A particle moves in a circular path under magnetic field. If its kinetic energy becomes four times, radius becomes:
A. r/2
B. r
C. 2r
D. 4r
Answer: C
r = √(2mK)/(qB), so r ∝ √K. If K becomes 4K, radius becomes 2r.
Q22.
A charged particle of mass m and charge q enters a magnetic field B normally. Time taken to complete half circle is:
A. πm/qB
B. 2πm/qB
C. m/qB
D. πqB/m
Answer: A
Cyclotron period T = 2πm/qB. Half circle time = T/2 = πm/qB.
Q23.
In a cyclotron, if magnetic field is doubled while oscillator frequency is unchanged, resonance for same particle:
A. remains valid
B. fails because required frequency doubles
C. fails because required frequency halves
D. depends on speed only
Answer: B
Cyclotron frequency f = qB/(2πm). If B doubles, required oscillator frequency doubles. If unchanged, resonance condition fails.
Q24.
A wire carrying current I is bent into a regular hexagon of side a. Magnetic field at centre is:
A. 3μ0I/(πa)
B. √3 μ0I/(πa)
C. 3√3 μ0I/(2πa)
D. μ0I/(2a)
Answer: B
For each side, perpendicular distance from the centre is d = a√3/2 and the end angles are 30° and 30°. Field due to one side is μ0I/(4πd)(sin30° + sin30°) = μ0I/(4πd). For six sides, B = 6μ0I/(4πd) = 3μ0I/(2πd) = √3 μ0I/(πa).
Q25.
A straight conductor of length 0.5 m carries current 4 A. It makes angle 30° with a magnetic field of 0.2 T. Magnetic force is:
A. 0.1 N
B. 0.2 N
C. 0.4 N
D. zero
Answer: B
F = BIL sinθ = 0.2 × 4 × 0.5 × sin30° = 0.2 N.
Q26.
A current loop is in uniform magnetic field. Which statement is correct?
A. Net force is always zero, torque may be non-zero
B. Net force is always non-zero
C. Torque is always zero
D. Both force and torque are always non-zero
Answer: A
In uniform magnetic field, force on opposite elements cancels, so net force on closed loop is zero. Torque τ = M × B may be non-zero.
Q27.
A loop of area A and current I is placed in magnetic field B. If magnetic potential energy is minimum, angle between magnetic moment and B is:
A. 0°
B. 90°
C. 180°
D. 45°
Answer: A
U = −MB cosθ. Minimum value is −MB, obtained when cosθ = 1, so θ = 0°.
Q28.
A charged particle moving with velocity v = 3î + 4ĵ enters magnetic field B = 2k̂. If charge q = 5 C, force vector is:
A. 40î − 30ĵ
B. 30î − 40ĵ
C. −40î + 30ĵ
D. 40î + 30ĵ
Answer: A
F = q(v × B). (3î + 4ĵ) × 2k̂ = 8î − 6ĵ. Multiplying by q = 5 gives F = 40î − 30ĵ.
Q29.
A particle has velocity vector exactly opposite to uniform magnetic field. The path of the particle is:
A. circle
B. helix
C. straight line
D. parabola
Answer: C
Magnetic force is qvB sinθ. Here θ = 180°, so sinθ = 0. Hence no force and particle moves straight.
Q30.
A proton and an alpha particle enter the same magnetic field normally with same speed. Ratio of radii rp : rα is:
A. 1 : 1
B. 1 : 2
C. 2 : 1
D. 1 : 4
Answer: B
r = mv/qB. Alpha particle has mass 4mp and charge 2e. rα = (4mpv)/(2eB)=2rp. Ratio = 1:2.
Q31.
An electron enters a magnetic field normally. Its angular frequency is:
A. eB/m
B. m/eB
C. eB/2πm
D. 2πm/eB
Answer: A
Angular cyclotron frequency ω = qB/m. For electron magnitude is eB/m.
Q32.
If a charged particle moves undeflected through crossed E and B fields, then after entering only magnetic field B, radius of path is:
A. mE/qB²
B. mB/qE²
C. qE/mB²
D. E/qB
Answer: A
Velocity selector gives v = E/B. In magnetic field alone, r = mv/qB = mE/(qB²).
Q33.
A circular coil has N turns, radius R and carries current I. Magnetic field at centre is B. If radius is doubled and number of turns is halved, current unchanged, new field is:
A. B/4
B. B/2
C. B
D. 2B
Answer: A
B = μ0NI/(2R). New B′ = μ0(N/2)I/[2(2R)] = B/4.
Q34.
The magnetic field on the axis of a circular loop at distance x from centre is maximum at:
A. x = 0
B. x = R
C. x = R/√2
D. x = √2R
Answer: A
B = μ0IR²/[2(R²+x²)3/2]. Denominator is minimum at x = 0, hence field is maximum at centre.
Q35.
A wire carrying current I is bent into a circle. If the same wire is bent into a circle of half radius by using only half of the wire length and same current, field at centre becomes:
A. B/2
B. B
C. 2B
D. 4B
Answer: C
For a circular loop, B = μ0I/(2R). If radius becomes R/2 with same current, field becomes 2B.
Q36.
A charged particle completes 10 revolutions in 2 μs in a uniform magnetic field. Its cyclotron frequency is:
A. 2 MHz
B. 5 MHz
C. 10 MHz
D. 20 MHz
Answer: B
Frequency = number of revolutions/time = 10/(2 × 10−6) = 5 × 106 Hz = 5 MHz.
Q37.
A current carrying loop has magnetic moment M. It is placed in field B. If it is rotated through small angle θ from stable equilibrium, restoring torque is approximately:
A. MBθ
B. −MBθ
C. MB/θ
D. zero
Answer: B
Torque magnitude τ = MB sinθ ≈ MBθ. Restoring torque acts opposite to displacement, so τ = −MBθ.
Q38.
A galvanometer has resistance G and full-scale current Ig. To convert into voltmeter of range V, series resistance should be:
A. V/Ig − G
B. Ig/V − G
C. VG/Ig
D. G − V/Ig
Answer: A
At full scale, V = Ig(G + R). Therefore R = V/Ig − G.
Q39.
A galvanometer has resistance 50 Ω and full scale current 1 mA. Series resistance required for 10 V voltmeter is:
A. 9950 Ω
B. 10000 Ω
C. 9500 Ω
D. 50 Ω
Answer: A
R = V/Ig − G = 10/0.001 − 50 = 10000 − 50 = 9950 Ω.
Q40.
A particle enters a magnetic field with velocity perpendicular to B. Which quantity remains constant?
A. velocity vector
B. momentum vector
C. kinetic energy
D. acceleration vector
Answer: C
Magnetic force is always perpendicular to velocity, so it does no work. Speed and kinetic energy remain constant, but velocity and momentum directions change.
Q41.
A square loop of side a carries current I. Magnetic field at its centre is:
A. 2√2 μ0I/(πa)
B. √2 μ0I/(πa)
C. μ0I/(2a)
D. μ0I/(πa)
Answer: A
For one side, d = a/2 and θ = 45°. Bone side = μ0I/(4πd)(2sin45°). Four sides give B = 2√2 μ0I/(πa).
Q42.
A current carrying wire is placed along magnetic field. The force on it is:
A. maximum
B. minimum and zero
C. BIL
D. BIL/2
Answer: B
F = BIL sinθ. If wire is along field, θ = 0°, so F = 0.
Q43.
A loop has magnetic moment 0.2 A m² and is placed in 5 T field. Maximum torque is:
A. 0.1 N m
B. 1 N m
C. 5 N m
D. 25 N m
Answer: B
Maximum torque τmax = MB = 0.2 × 5 = 1 N m.
Q44.
Two ions have same charge but masses m and 4m. They are accelerated by same potential and enter same B normally. Ratio of radii is:
A. 1 : 2
B. 1 : 4
C. 2 : 1
D. 4 : 1
Answer: A
r = (1/B)√(2mV/q). Hence r ∝ √m. For masses m and 4m, ratio = 1:2.
Q45.
A long wire carries current I upward. At a point to the east of wire, direction of magnetic field is:
A. north
B. south
C. vertically upward
D. vertically downward
Answer: A
Use right-hand thumb rule. Thumb upward along current; curled fingers give magnetic field. At east side, field points north.
Q46.
The magnetic field inside a long solenoid is B = μ0nI. If length and number of turns are both doubled, keeping current same, field becomes:
A. B/2
B. B
C. 2B
D. 4B
Answer: B
n = N/L. If both N and L are doubled, n remains same. Hence B remains unchanged.
Q47.
A charged particle moves in a magnetic field. Its magnetic force can change:
A. speed only
B. kinetic energy only
C. direction of velocity only
D. both speed and kinetic energy
Answer: C
Magnetic force is perpendicular to velocity, so it changes direction of velocity but not speed or kinetic energy.
Q48.
A current loop is placed in uniform magnetic field with magnetic moment anti-parallel to B. The equilibrium is:
A. stable
B. unstable
C. neutral
D. impossible
Answer: B
Anti-parallel position has maximum potential energy U = +MB. Small rotation lowers energy, so it is unstable equilibrium.
Q49.
Magnetic field due to a very long straight wire at distance r is B. At distance 2r, the magnetic energy density becomes:
A. u/2
B. u/4
C. 2u
D. 4u
Answer: B
B ∝ 1/r. At 2r, field becomes B/2. Magnetic energy density u = B²/(2μ0), so new density = u/4.
Q50.
A beam of positive ions enters a region with magnetic field into the page. If the ions initially move to the right, they are deflected:
A. upward
B. downward
C. into the page
D. out of the page
Answer: A
For positive charge, F = q(v × B). v is right (+x), B is into page (−z). Hence v × B = +y, i.e. upward.
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