Physics

CHAPTER 1. Rotational Dynamics

1. Distinguish Between Centripetal force and Centrifugal force.

2. What is the banking of road and obtain an expression for the maximum/minimum
safety speed of vehicles moving along curve horizontal road.
3. Draw the neat labelled diagram of the conical pendulum state the expression for
its periodic time and the term of length.
4. A bob tied to a string is whirled in a non-uniform vertical circular motion.
Derive the expression for tension in the string at uppermost and lowermost
position.
5. Show that the difference in tensions in the string at the highest and lowest
positions is 6 mg.
6. Show that the K.E of a rotating body about a given axis is equal to 1/2 lω².
7. State and prove the theorem of parallel/perpendicular axes
8. State and prove the law of conservation of angular momentum.
9. Show that / prove that L =Iα.
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Chapter 2.
Mechanical Properties of Fluids
1. Define a) Intermolecular force b) adhesive force
c) Cohesive force d) Range of molecules e) Surface Film.

2. Explain the phenomenon of surface tension on the basis of molecular theory.

3. What is Surface energy? Obtain the relation between Surface Tension and surface
energy.

4. Define surface tension. State its SI unit and dimensions.

5. Define angle of contact? State its four characteristics.

6. Explain the effect of impurity on S.T?

7. Derive Laplace's law for the spherical membrane of the bubble due to surface
tension.

8. Define capillary and capillarity.Obtain the expression for capillary rise or

fall ?

9. Define critical velocity. Write the expression for the Reynolds Number.

10. Define Velocity gradient and coefficient of viscosity?

11. Explain Newton’s law of viscosity. Hence define coefficient of viscosity.

12. State the Stokes law. State its formula for Terminal Velocity.

13. Obtain an expression for terminal velocity of a spherical object falling

through a viscous fluid.

14. Explain the formation of concave and convex surface of a liquid on the basis of
molecular theory.

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PART 2
Chapter 3. Kinetic Theory of Gases and Radiation
1. On the basis of kinetic theory of gases. Derive an expression for the
pressure exerted by a gas.
2. Define R.M.S velocity / speed.
3. Explain Mayers relation for a) Monoatomic Gas b) Dia-atomic c) polyatomic
molecules.
4. Define a) coefficient of absorption b) coefficient of reflection c) coefficient
of
transmission?
5. What is perfectly black body and Draw the labelled diagram?
6. Explain Ferry's black body.
7. Explain black body radiation spectrum in term of wavelength?
8. State and explain a) Wien's displacement law b) Stefan law ?
9. Define emissive power and coefficient of emission of a body?
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Chapter 4. Thermodynamics

1. State first law of thermodynamics.

2. State Zeroth law of thermodynamics.

3. Define internal energy.

4. What is meant by thermal equilibrium?

OR What is meant by the expression ‘two systems are in thermal equilibrium?

5. Work Done during a thermodynamics process.

6. Explain classification of thermodynamic systems.

7. What is a thermodynamic process? Give an exmple.

8. On the basis of the kinetic theory of gases, explain

(i) positive work done by a system (ii) negative work done by a system.

9. Obtain an expression for the work done by a gas. OR Show that the work done by a
gas is
W = Vf
∫ PdV
Vi

10. What is an isothermal process? Obtain an expression for the work done by a gas
in an isothermal process.

11. Explain a) Reversible / Irreversible process

b) Isothermal process.
c) Isobaric process.
d) Isochoric process.
e ) adiabatics process /
cyclic process.
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PART 3
Chapter 5. Oscillations

1. Define linear S.H.M ? Obtain an expression for differential Equation of linear

SHM.

2. From differential equation of linear SHM, obtain an expression for acceleration,

velocity and displacement of particle in SHM ?

3. Discuss the composition of two SHM along the same path having same period and
find the resultant amplitude and initial phase?

4. Deduce the expressions for Kinetic Energy and Potential Energy and total energy
of a particle performing SHM.

5. Define Simple pendulum. Derive expression for the period of motion of simple
pendulum. Also state on which factor it depends?

6. Define Angular SHM and obtain its differential equation?

Chapter 6. Superposition of Waves

1. Equation stationary wave on stretched string and condition of nodes and
antinodes ?
2. State the properties of Stationary wave.
3. Distinguish between a) progressive wave and stationary wave
b) Free and Force vibration?
4. Obtain the expression for the frequency of the first three modes of vibration of
stretched string between two rigid support with the help of neat labelled diagram.
Hence show that all harmonics are present in these vibrations.
5. Draw the neat labelled diagram of the first three modes of vibration of air
column in a pipe open at one end (or closed at one end).
Obtain the formule for the frequency of the first three modes of vibration of air
column in the same pipe. Also in this case show that odd harmonics are present.
6. Obtain an expression for the frequency of the first three modes of vibration of
air column in the pipe open at both end with neat labelled diagram. Also in this
case show that even harmonics are present.
7. Show that the fundamental frequency of vibration of the air column in a pipe
open at both ends is double that of a pipe of the same length and closed at one
end.
8. Two organ pipes closed at one end have the same diameters but different lengths.
Show that the end correction at each end is where the symbols have their usual
meanings.
9. What are beats? Define (1) the period of beats (2) beat frequency.
10. Explain the production of beats and deduce analytically the expression for beat
frequency.
OR
Discuss analytically the formation of beats and show that
(1) the beat frequency equals the difference in frequencies of two interfering
waves
(2) the waxing and waning occur alternately and with the same period.
11. Explain any two applications of beats.
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Chapter 7. Wave Optics

1 Give a brief account of Huygens’ wave theory of light. State its merits and
demerits.
2. State Huygens’ principle.
3. Explain the construction and propagation of a plane wavefront using Huygens’
principle.
4. Explain the construction and propagation of a spherical wavefront using Huygens’
principle.
5.Explain the phenomenon of polarization of light by reflection.
OR
Explain Brewster’s law.
6. Describe with a neat labelled ray diagram the Fraunhofer diffraction pattern due
to a single slit. Obtain the expressions for the positions of the intensity minima
and maxima. Also obtain the expression for the width of the central maximum.
7. In Young’s double-slit experiment, a glass slide of refractive index ng and
thickness b is placed in front of one of the slits.
What happens to the interference pattern and fringe width ?
Derive an expression for the positions of the bright fringes in the interference
pattern.
8. State and explain Rayleigh’s criterion for minimum resolution.
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PART 4
Chapter 8. Electrostatics
1.Obtain an expression for the electric field intensity at a point outside a
charged conducting spherical shell.
Hence, obtain an expression for the electric intensity
(i) on the surface of (i.e. just outside) the spherical conductor.
(ii) inside the spherical conductor.
2. Obtain an expression for the electric field intensity at a point outside an
infinitely long charged cylindrical conductor.
3. Obtain an expression for the electric field intensity at a point outside a
uniformly charged thin infinite plane sheet.
4. Obtain an expression for the electric potential energy of a system of two
isolated point charges.
5. Obtain an expression for the electric potential at a point due to an isolated
point charge.
6. Derive an expression for the electric potential at a point due to a short
electric dipole. Hence, write the expression for the electric potential at a point
(i) on the dipole axis
(ii) on the dipole equator.
7. Derive an expression for the potential energy of a system of two point charges.
8. Obtain an expression for the potential energy of a configuration of N point
charges.
9. Derive an expression for the electric potential energy of an electric dipole in
a uniform electric field.
OR
Derive an expression for the total work done in rotating an electric dipole through
an angle θ in a uniform electric field.
10. Derive an expression for the effective or equivalent capacitance (capacity) of
a combination of a number of capacitors connected in series.
OR
Derive an expression for the effective capacitance of three capacitors connected in
series.
11. Explain the effect of a dielectric on the capacitance of a isolated charged
parallel-plate capacitor.
Hence, show that if a dielectric of relative permitivity (dielectric constant) k
completely fills the space between the plates, the capacitance increases by a
factor k.
12. Show that the energy of a charged capacitor is 1/2 CV². Also, express this in
other forms.
OR
Derive an expression for the energy stored in a charged capacitor. Express it in
different forms.
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Chapter 9. Current Elecricity

1 State Kirchhoff’s first law or current law or junction law.

2. What is the sign convention used for Kirchhoff’s first law? Explain with an
example.
3. What is the sign convention used for Kirchhoff’s first law? Explain with an
example.
4. What is the sign convention used for Kirchhoff’s second law ? Explain with an
example.
5. Obtain the balancing condition in case of Wheatstone’s network.
6. Explain with the help of neat circuit diagram, how you determine the unknown
resistance by using a meter-bridge.
7. Describe how a potentiometer is used to compare the emfs of two cells by
combination method.
8. Describe with the help of a neat circuit diagram how you will determine the
internal resistance of a cell by usinhg a potentiometer.
9. State the advantages of a potentiometer over a voltmeter.
10. Explain how a moving-coil galvanometer is converted into an ammeter. Derive the
necessary formula.
11. Explain how a moving-coil galvanometer is converted into a voltmeter. Derive
the necessary formula.
12. Distinguish between an ammeter and a voltmeter.
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PART 5
Chapter 10. Magnetic Fields due to Eletric Current

1 (a) State the factors which the magnetic force on a charge depends upon and write
its vector cross product relationship.
(b) Hence state the expression for the Lorentz force on a charge due to an
electric field as well as a magnetic field.
(c) Hence discuss the magnetic force on a charged particle which is
(i) moving parallel to the magnetic field (ii) stationary.
2. Define the SI unit of magnetic induction from Lorentz force.
3. Obtain an expression for the magnetic force acting on the straight wire carrying
a current. Also extend this formula for a wire of arbitrary shape.
4. Derive an expression for the net torque on a rectangular current-carrying loop
placed in a uniform magnetic field with its rotation axis perpendicular to the
field.
5. Describe the construction of a suspended-type moving-coil galvanometer with a
neat labelled diagram.
6. State working of a moving- coil galvanometer (suspended-coil type).
7. State the Bio-Savart law (Laplace law) for the magnetic induction produced by a
current el-ement. Express it in vector form.
8. Using Biot-Savart’s law, obtain the expression for the magnetic induction near a
straight infinitely long current-carrying wire.
9. Show that currents in two long, straight, parallel wires exert forces on each
other. Derive the expression for the force.
OR
Derive an expression for the force per unit length between two infinitely long
parallel conductors carrying current and hence define the ampere.
10. Obtain an expression for the magnetic induction produced by a current in a wire
in the shape of a circular arc at its centre of curvature.
Hence obtain an expression for the magnetic induction at the centre of a circular
coil carrying a current.
11. Derive an expression for the magnetic induction at a point on the axis of a
circular coil carrying a current.
12. State and explain Ampere’s circuital law.
13. Using Ampere’s law, obtain an expression for the magnetic induction near a
current-carrying straight, infinitely long wire.
14. Using Ampere’s law, derive an expression for the magnetic induction inside an
ideal solenoid carrying a steady current.
15. Using Ampere’s law, derive an expression for the magnetic induction inside an
ideal toroid carrying a steady current.
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Chapter 11. Magnetic Materials

1. Explain the directional characteristic of a bar magnet. State its use.

2. Obtain an expression for orbital magnetic moment of an electron revolving about
the nucleus of an atom.
OR
Show that orbital magnetic moment of an electron revolving about the nucleus of an
atom is proportional to its angular monmentum
3. State formula for gyromagnetic ratio. Find the gyromagnetic ratio of Electron. (
Given: me = 9.1 ×10⁻³¹kg, and e= 1.6 × 10⁻¹⁹ C).
4. What is the gyromagnetic ratio of an orbital electron ? State its dimensions and
the SI unit.
5. State the vector form of the formula of orbital magnetic moment of an electron
revolving about the nucleus of an atom. State why it is Negative?
6. Obtain the expression for Bohr Magneton. State its value with unit.
7. Explain magnetization of a material.
8. Define magnetization. State its dimensions and the SI unit.
OR
Define magnetization. State its formula and SI unit.
9. Define magnetic intensity. State its dimensions and the SI unit.
10. What is the magnetic susceptibility of a medium?
11. Is magnetic susceptibility a dimensionless quantity? Why?
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CHAPTERR 12. ELECTROMAGNETIC INDUCTION

1) Express Faraday-Lenz’s law of electromagnetic induction in an equation form.
2) Determine the motional emf induced in a straight conductor moving in a uniform
magnetic field with constant velocity.
3) Find an expression for the power expended in pulling a conducting loop out of a
magnetic field.
4) What are eddy currents? State applications of eddy currents.
5) Explain and define the self inductance of a coil.
6) State and define the SI unit of self inductance. Give its dimensions.
7) Obtain an expression for the self inductance of a solenoid.
8) Derive the expression for the energy stored in the magnetic field of an
inductor.
9) Obtain an expression for the self inductance of a solenoid.
10) Explain and define mutual inductance of a coil with respect to another coil.
11) Show that the mutual inductance for a pair of inductively coupled
coils/circuits of self inductances L1 and L₂ is given by M = K√L1L₂ , where K is
the coupling coefficient.
12) What is a transformer? State the principle of working of a transformer.
13) Describe the construction and working of a transformer with a neat labelled
diagram.

14) Distinguish between a step-up and a step-down transformers.

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Chapter 13 AC CIRCUITS

1) What is the average or mean value of an alternating emf? Obtain the expression
for it.
2) What is the rms value of an alternating current? Find the relation between the
rms value and peak value of an alternating current that varies sinusoidaily with
time.
3) What is a phasor? What is a phasor diagram ? Illustrate it with an example.
4) An alternating emf e = e₀ sin ωt is applied to a resistor of resistance R.
Write the expression for the current through the resistor. Show the variation of
emf and current with ωt.
Draw a phasor diagram to show emf and current.
5) Draw a Phasor diagram showing e and i in the case of a purely inductive circuit.
6) An alternating emf is applied to an LR circuit. Assuming the expression for the
current, obtain the expressions for the applied emf and the effective resistance of
the circuit. Assume the inductor and resistor to be ideal.
Draw the phasor diagram showing the emf and current.
7) Draw the impedance triangle for a series LCR AC circuit and write the
expressions for the im-pedance and the phase difference between the emf and the
current.
8) What is an acceptor circuit ? State its use.
9) Explain electrical resonance in an LC parallel circuit. Deduce the expression
for the resonant frequency of the circuit.
10) What is a rejector circuit? State its use.
11) How are oscillations produced using an inductor and a capacitor?
12) Explain electrical resonance in an LCR series circuit.
Deduce the expression for the resonant frequency of the circuit.
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Chapter 14 Dual Nature of Radiation and Matter

1) With a neat diagram, describe the apparatus to study the characteristics of

photoelectric effect.
2) In the experiment to study photoelectric effect, describe the effects of the
frequency and intensity of the incident radiation on the photoelectric current, for
a given emitter material and potential difference across the photoelectric cell.
3) Define (1) Threshold frequency (2) Threshold wavelength (3) Stopping potential.
4) State the characteristics of photoelectric effect.
5) Define photoelectric work function of a metal.
6) Write Einstein’s photoelectric equation and explain its various tends. How does
the equation explain the various features of the photoelectric effect?
7) Explain wave-particle duality of electromagnetic radiation.
8) State the de Broglie hypothesis and the de Broglie equation.
9) Derive an expression for the de Broglie wavelength associated with an electron
accelerated from rest through a potential difference V. Consider the
nonrelativistic case.
10) Derive an expression for the de Broglie wavelength.
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Chapter 15 Structure of Atoms and Nuclei
1) Explain Thomson’s model of the atom. What are its drawbacks?
2) Explain Rutherford’s model of the atom. State the difficulties faced by
Rutherford’s model of the atom.
3) State and explain the formula that gives wavelengths of lines in the hydrogen
spectrum.
4) State the Postulates of Bohr’s atomic model.
5) speed of an electron in a Bohr orbit. Hence, show that it is inversely
proportional to the principal quantum number.
6) Derive an expression for the radius of the nth Bohr orbit in an atom. Hence,
show that the radius of the orbit is directly proportional to the square of the
principal quantum number.
7) Show that the energy of the electron in the nth stationary orbit in the hydrogen
atom is Eₙ = -RHch/n².
8) Draw a neat, labelled energy level diagram for the hydrogen atom. Hence explain
the different series of spectral lines for hydrogen.
9) Obtain the ratio of the longest wavelength of spectral line in the Paschen
series to the longest wavelength of spectral line in the Brackett series.
10) State the limitations of Bohr’s atomic model.
11) On the basis of the de Broglie hypothesis, obtain Bohr’s condition of
quantization of angular momentum.
12) State the law of radioactive decay and express it in the exponential form.
OR
State the law of radioactive decay. Hence derive the relation N = N₀e-λt, where the
symbols have their usual meanings.
13) Define half-life a radioactive element and obtain the relation between half-
life and decay constant.
14) What is meant by average life or mean life of a radioactive species ? How is it
related to the half-life?
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Chapter 16 Semiconductor Devices
1) Draw a neat block diagram of a dc power supply and state the function of each
part.
OR
With the help of a block diagram, explain the scheme of a power supply for
obtaining dc output voltage from ac line voltage.
2) Explain full wave rectifier. State advantages of it.
3) Distinguish between a half-wave rectifier and full-wave rectifier.
4) Explain ripple in the output of a rectifier. What is ripple factor?
5) Explain the action of a capacitive filter with necessary diagrams.
6) What is a photodiode? Explain the I-V characteristics of a photodiode.
7) What is (i) dark current (ii) dark resistance of a photodiode?
8) State any advantages and disadvantages of a photodiode.
9) State any two applications of photodiodes.
10) What is a solar cell ? State the principle of its working. State any four uses
of solar cells.
11) State the material selection criteria for solar cells.
12) What is a light-emitting diode (LED)? Describe with a neat diagram the
construction of an LED.
13) State any four disadvantages of an LED. State any four applications of LEDs.
14) Explain the working of an npn transistor with a neatly labelled circuit
diagram.
15) Draw a neat labelled circuit diagram to study the characteristics of a
transistor in common- emitter configuration.
16) What is an amplifier? Draw a neat circuit diagram of a transistor CE- amplifier
and explain its working.
17) Define the following logic gates :
(1) AND
(2) OR
(3) NOT.
Give the logic symbol, Boolean expression and truth table of each.
18) Define the logic gates (1) NAND (2) NOR.
Give the logic symbol, Boolean expression and truth table of each.
How are the above gates realized from the basic gates?