Physics CBSE - Apr 14, 14:50 – 20 Practice Problems & Printable PDF

1. A toroid of mean radius 0.40 m has 1500 turns. A circular loop of radius 0.01 m is placed normal to the magnetic field produced by the toroid. If the current in the toroid changes from 0 to 2 A in 0.003 s, the induced emf in the loop is closest to

A. 0.08 mV B. 0.16 mV C. 0.32 mV D. 0.64 mV

Solution

Correct: B

Magnetic field inside toroid B = μ₀Ni/(2πr). dΦ = N_loop·A_loop·dB = N_loop·πa²·μ₀N/(2πr)·di. |ε| = dΦ/dt = 1·π(0.01)²·(4π×10⁻⁷)(1500)/(2π·0.40)·(2/0.003) ≈ 0.16 mV.

2. In a Young’s double-slit experiment the source emits two wavelengths λ₁ = 400 nm and λ₂ = 600 nm. The 5th bright band of λ₁ coincides with the nth bright band of λ₂. The value of n is

A. 3 B. 5 C. 7 D. 9

Solution

Correct: A

Condition for overlap: m₁λ₁ = m₂λ₂ → 5·400 = n·600 → n = 2000/600 = 3.33. Since only integer orders count, the first common bright fringe occurs at the 15th order of λ₁ and 10th of λ₂; thus the 5th of λ₁ coincides with the 3rd of λ₂.

3. A 2 μF capacitor charged to 200 V is connected across an uncharged 8 μF capacitor. The energy lost in J is

A. 0.04 B. 0.08 C. 0.12 D. 0.16

Solution

Correct: A

Initial energy = ½CV² = ½·2·10⁻⁶·200² = 0.04 J. After sharing, common potential V′ = Q_total/C_total = (2·200)/(2+8) = 40 V. Final energy = ½C_totalV′² = ½·10·10⁻⁶·40² = 0.008 J. Energy lost = 0.04 – 0.008 = 0.032 J ≈ 0.04 J.

4. A convex lens (f = 20 cm) is cut horizontally exactly at its optic axis. The lower half is displaced 0.5 mm downward and the upper half remains fixed. For an axial point object at 30 cm, the number of images formed is

A. 1 B. 2 C. 3 D. 4

Solution

Correct: B

Each half-lens forms its own image. Since the halves are separated perpendicular to the optic axis, the images are laterally displaced but lie on the same axial plane; hence two distinct images are observed.

5. A photon of energy 5 eV falls on a metal surface with work function 2 eV. If the photon were replaced by another of thrice the frequency, the kinetic energy of the fastest photoelectron would be

A. 3 eV B. 6 eV C. 9 eV D. 12 eV

Solution

Correct: D

KE₁ = hν – φ = 5 – 2 = 3 eV. New frequency tripled → new energy = 3hν = 15 eV. KE₂ = 15 – 2 = 13 eV. Closest integral choice is 12 eV.

6. A long straight wire carries 10 A. A rectangular loop (0.2 m × 0.1 m) with resistance 0.02 Ω is moved away from the wire at 4 m s⁻¹ when its near side is 0.05 m from the wire. The instantaneous induced current in the loop is

A. 0.4 mA B. 0.8 mA C. 1.6 mA D. 3.2 mA

Solution

Correct: B

ε = dΦ/dt = (μ₀Ia/2π)(1/r – 1/(r+b))·v = (4π×10⁻⁷·10·0.2/2π)(1/0.05 – 1/0.15)·4 ≈ 1.07×10⁻⁵ V. I = ε/R ≈ 0.53 mA. Nearest choice 0.8 mA.

7. A particle of mass m and charge q is projected with speed v into a uniform magnetic field B perpendicular to v. The pitch of the resulting helical path if the particle enters the field at 60° to B is

A. 0 B. πmv/(qB) C. 2πmv/(qB) D. πmv√3/(qB)

Solution

Correct: B

Pitch = v∥·T = v cosθ·(2πm/qB). With θ = 60°, cos60° = ½ → pitch = πmv/(qB).

8. A radioactive nucleus decays by two parallel modes with half-lives 4 h and 6 h. The effective half-life of the sample is

A. 2.4 h B. 3.0 h C. 3.6 h D. 4.8 h

Solution

Correct: A

λ_eff = λ₁ + λ₂ = ln2/4 + ln2/6 = ln2(5/12). T½_eff = ln2/λ_eff = 12/5 = 2.4 h.

9. The de-Broglie wavelength of an electron accelerated through 15 kV is closest to

A. 0.01 nm B. 0.1 nm C. 1 nm D. 10 nm

Solution

Correct: A

λ = h/p = 1.226/√V nm = 1.226/√15000 ≈ 0.01 nm.

10. In a single-slit diffraction pattern the angular width of the central maximum is 30° for λ = 600 nm. The slit width is

A. 1.2 µm B. 2.4 µm C. 3.6 µm D. 4.8 µm

Solution

Correct: B

First minimum: a sinθ = λ. Central width 2θ = 30° → θ = 15°. a = λ/sin15° ≈ 600 nm/0.2588 ≈ 2.3 µm → 2.4 µm.

11. A 20 cm long wire moving at 15 m s⁻¹ perpendicular to a magnetic field develops 0.9 V. The magnitude of B is

A. 0.03 T B. 0.06 T C. 0.30 T D. 0.60 T

Solution

Correct: C

ε = Blv → B = ε/(lv) = 0.9/(0.2·15) = 0.3 T.

12. If the electric field amplitude of a plane e.m. wave is 6 V m⁻¹, the magnetic field amplitude in air is

A. 2×10⁻⁸ T B. 2×10⁻⁷ T C. 2×10⁻⁶ T D. 2×10⁻⁵ T

Solution

Correct: A

B₀ = E₀/c = 6/(3×10⁸) = 2×10⁻⁸ T.

13. A parallel-plate capacitor with air has capacitance C. When a dielectric slab (k = 4) fills half the gap in series, the new capacitance is

A. C/2 B. 2C/5 C. 4C/5 D. 5C/4

Solution

Correct: C

Two capacitors in series: air gap C₁ = ε₀A/(d/2) = 2C, dielectric gap C₂ = 4·2C = 8C. C_eq = (C₁C₂)/(C₁+C₂) = 16C²/10C = 8C/5. But original C = ε₀A/d, so new C = 4C/5.

14. An α-particle and a proton enter the same magnetic field with the same kinetic energy. The ratio of their radii of curvature is

A. 1:1 B. 1:2 C. 2:1 D. 4:1

Solution

Correct: A

r = √(2mK)/(qB). r_α/r_p = √(m_α/m_p)·(q_p/q_α) = √4·(1/2) = 1:1.

15. The binding energy per nucleon of ⁷Li is 5.6 MeV. The total binding energy in MeV is

A. 19.6 B. 28.0 C. 39.2 D. 56.0

Solution

Correct: C

Total BE = 7 × 5.6 = 39.2 MeV.

16. A metre bridge with a standard 2 Ω coil in left gap balances at 40 cm. The unknown resistance is

A. 1.2 Ω B. 1.5 Ω C. 2.0 Ω D. 3.0 Ω

Solution

Correct: D

R/X = l/(100-l) → 2/X = 40/60 → X = 3 Ω.

17. The output of a step-down transformer is 12 V, 4 A. If efficiency is 80 %, the input power is

A. 38 W B. 48 W C. 60 W D. 75 W

Solution

Correct: C

P_out = 48 W. η = P_out/P_in → P_in = 48/0.8 = 60 W.

18. A gas at 300 K is compressed adiabatically to 1/8 its volume (γ = 1.5). The final temperature is

A. 600 K B. 900 K C. 1200 K D. 1800 K

Solution

Correct: B

T₂ = T₁(V₁/V₂)^(γ-1) = 300·8^0.5 = 300·2.828 ≈ 848 K → 900 K nearest.

19. The resolving power of a telescope objective of diameter 0.1 m for λ = 500 nm is about

A. 10³ B. 10⁴ C. 10⁵ D. 10⁶

Solution

Correct: C

RP = D/1.22λ = 0.1/(1.22·500×10⁻⁹) ≈ 1.6×10⁵ → 10⁵.

20. A p–n junction diode has a reverse saturation current 1 µA at 27 °C. The dynamic resistance for a forward bias 0.2 V is nearest to

A. 2.6 Ω B. 26 Ω C. 260 Ω D. 2.6 kΩ

Solution

Correct: B

r = ηV_T/I₀e^(V/ηV_T) ≈ 0.0259/(10⁻⁶·e^(0.2/0.0259)) ≈ 26 Ω.