A radioactive nucleus has half-life of 10 days. After 30 days, the fraction of original nuclei remaining is:

The correct answer is C: 1/8. Number of half-lives = 30/10 = 3. Remaining fraction = (1/2)³ = 1/8

A conducting sphere of radius 10 cm carries a charge of 5 μC. The electric field at a distance of 5 cm from the center inside the conductor is:

The correct answer is A: 0 N/C. Inside a conductor in electrostatic equilibrium, the electric field is always zero regardless of position or charge distribution

When light passes through a glass slab of thickness t and refractive index n, the lateral displacement is maximum when the angle of incidence is:

The correct answer is D: 60°. Lateral displacement d = t × sin(i - r)/cos(r). Displacement is maximum when ∂d/∂i = 0, which occurs approximately at high incident angles, practically around 60°

The transconductance g_m of a MOSFET in saturation is:

The correct answer is A: ∂I_D/∂V_GS. Transconductance g_m = ∂I_D/∂V_GS measures how much the drain current changes with gate voltage, a key figure of merit in MOSFET amplifier design.

In an isobaric process, 5 moles of a monoatomic ideal gas are heated from 300 K to 400 K. What is the heat supplied? (R = 8.314 J/(mol·K))

The correct answer is C: Q = 62.355 kJ. For isobaric process: Q = nCₚΔT. For monoatomic gas, Cₚ = (5/2)R. Q = 5 × (5/2) × 8.314 × 100 = 62.355 kJ

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JEE Physics
Semiconductors

Physics questions for JEE Main — Mechanics, Electrostatics, Optics, Modern Physics.

23 Q 9 Topics Take Mock Test

Difficulty: All Easy Medium Hard 11–20 of 23

Topics in JEE Physics

All Mechanics 100 Thermodynamics 100 Electrostatics 100 Current Electricity 100 Magnetism 100 Optics 100 Modern Physics 100 Semiconductors 100 Waves 100

Q.11 Easy Semiconductors

A zener diode is used in reverse bias to:

A Amplify signals

B Regulate voltage

C Detect light

D Switch circuits

Correct Answer: B. Regulate voltage

EXPLANATION

Zener diodes are operated in reverse bias within the zener breakdown region to maintain constant voltage across them, useful for voltage regulation.

Test

Q.12 Easy Semiconductors

When a semiconductor is doped with donor atoms, the Fermi level shifts:

A Towards the valence band

B Towards the conduction band

C Remains at the band center

D Outside the band gap

Correct Answer: B. Towards the conduction band

EXPLANATION

Donor doping creates an n-type semiconductor, shifting the Fermi level closer to the conduction band due to increased electron concentration.

Test

Q.13 Easy Semiconductors

The band gap energy of Germanium at room temperature (300K) is approximately:

A 0.66 eV

B 1.12 eV

C 1.44 eV

D 3.0 eV

Correct Answer: A. 0.66 eV

EXPLANATION

Germanium has a band gap of ~0.66 eV at room temperature, making it a narrow band gap semiconductor used in infrared applications.

Test

Q.14 Easy Semiconductors

In a p-n junction diode at thermal equilibrium, the direction of the electric field in the depletion region is:

A From n-region to p-region

B From p-region to n-region

C Perpendicular to the junction

D No electric field exists

Correct Answer: B. From p-region to n-region

EXPLANATION

At thermal equilibrium, the built-in electric field points from the p-region (positive) to n-region (negative) to oppose further diffusion of carriers.

Test

Q.15 Easy Semiconductors

The pinch-off voltage Vp in a JFET is the gate voltage at which:

A The channel completely depletes and current becomes zero

B The device enters saturation region

C Maximum drain current flows

D Avalanche breakdown occurs

Correct Answer: A. The channel completely depletes and current becomes zero

EXPLANATION

At pinch-off voltage, the depletion region extends completely across the channel width, cutting off the flow of carriers and reducing drain current to nearly zero (IDSS becomes zero).

Test

Q.16 Easy Semiconductors

Which of the following statements about the bandgap of semiconductors is correct?

A Bandgap increases with temperature for all semiconductors

B Bandgap decreases with temperature (negative temperature coefficient)

C Bandgap is independent of temperature

D Bandgap becomes zero at high temperatures

Correct Answer: B. Bandgap decreases with temperature (negative temperature coefficient)

EXPLANATION

The bandgap energy decreases with increasing temperature at a rate of approximately -2 to -4 meV/K, described by the Varshni equation: Eg(T) = Eg(0) - αT²/(T+β)

Test

Q.17 Easy Semiconductors

When a p-type semiconductor is doped with donor atoms instead of acceptors, what happens to the Fermi level position?

A Fermi level moves closer to the valence band

B Fermi level moves closer to the conduction band

C Fermi level remains at the same position

D Fermi level position becomes undefined

Correct Answer: B. Fermi level moves closer to the conduction band

EXPLANATION

Adding donor atoms to a p-type semiconductor introduces electrons, shifting the material towards n-type behavior and moving the Fermi level toward the conduction band.

Test

Q.18 Easy Semiconductors

In an intrinsic semiconductor at room temperature, if the bandgap energy is Eg, what is the relationship between electron and hole concentrations?

A ne = nh always

B ne > nh due to higher electron mobility

C ne = nh = ni (intrinsic carrier concentration)

D ne and nh depend only on doping concentration

Correct Answer: C. ne = nh = ni (intrinsic carrier concentration)

EXPLANATION

In an intrinsic semiconductor, the number of electrons equals the number of holes as they are generated in pairs. Both equal the intrinsic carrier concentration ni.

Test

Q.19 Easy Semiconductors

An LED emits light because:

A Holes and electrons recombine radiatively in direct bandgap material

B Thermal excitation generates photons

C Phonon scattering produces light

D Fermi level oscillation generates electromagnetic waves

Correct Answer: A. Holes and electrons recombine radiatively in direct bandgap material

EXPLANATION

In LEDs (forward biased p-n junctions in direct bandgap semiconductors like GaAs), electron-hole recombination releases energy as photons. Indirect bandgap materials (Si, Ge) produce mainly heat.

Test

Q.20 Easy Semiconductors

A p-type semiconductor is created by doping silicon with:

A Phosphorus

B Arsenic

C Boron

D Antimony

Correct Answer: C. Boron

EXPLANATION

Boron is a Group III element (trivalent) that acts as an acceptor in silicon, creating holes and forming p-type semiconductor. Phosphorus, Arsenic, and Antimony are Group V elements (pentavalent) forming n-type semiconductors.

Test

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Semiconductors