1. Rotational
Dynamics
Content:
Study of rotational motion, torque, angular momentum, and the equations of
motion for rotating bodies.
Objective:
To understand the principles governing rotational motion and apply them to
solve problems involving rotating objects.
2. Mechanical Properties of Fluids
Content:
Examination of fluid mechanics, including viscosity, surface tension, buoyancy,
and Bernoulli’s principle.
Objective:
To analyze fluid behavior and apply fluid mechanics principles in realworld
situations such as flow in pipes and the behavior of gases.
3. Kinetic Theory of Gases and Radiation
Content:
Exploration of the kinetic theory, gas laws, and the behavior of gases, along
with concepts of radiation and thermal equilibrium.
Objective:
To understand the molecular basis of gas behavior and the laws governing their
interactions, including thermal radiation.
4. Thermodynamics
Content:
Study of laws of thermodynamics, heat transfer, engines, and entropy.
Objective:
To apply thermodynamic principles to various systems and understand energy
transformations in physical processes.
5. Oscillations
Content:
Examination of simple harmonic motion (SHM), oscillatory systems, and energy in
oscillations.
Objective:
To analyze oscillatory motion and its applications in realworld systems such as
pendulums and springs.
6. Superposition of Waves
Content:
Study of wave interference, standing waves, and the principle of superposition.
Objective:
To understand the behavior of waves when they interact and apply the principles
of superposition to analyze wave phenomena.
7. Wave Optics
Content:
Exploration of interference, diffraction, and polarization of light waves.
Objective:
To apply wave principles to optical phenomena and understand how light behaves
as a wave.
8. Electrostatics
Content:
Study of electric charges, Coulomb's law, electric fields, and potentials.
Objective:
To understand the principles of electrostatics and apply them to analyze
electric forces and fields.
9. Current Electricity
Content:
Examination of electric current, Ohm's law, circuits, and electrical
resistance.
Objective:
To analyze electric circuits, understand current flow, and apply concepts of
current electricity to practical applications.
10. Magnetic Fields due to Electric Current
Content:
Study of magnetic fields generated by electric currents, Ampère's law, and
applications.
Objective:
To understand the relationship between electricity and magnetism and apply this
knowledge to analyze magnetic fields produced by currents.
11. Magnetic Materials
Content:
Exploration of magnetic properties of materials, types of magnetism, and
applications of magnetic materials.
Objective:
To classify materials based on their magnetic properties and understand their
practical applications in technology.
12. Electromagnetic Induction
Content:
Study of Faraday’s laws of induction, Lenz's law, and applications of
electromagnetic induction.
Objective:
To understand the principles of induction and apply them in contexts such as
generators and transformers.
13. AC Circuits
Content:
Examination of alternating current (AC) circuits, impedance, and reactance.
Objective:
To analyze AC circuits and understand their behavior, including phase
relationships and energy transfer.
14. Dual Nature of Radiation and Matter
Content:
Study of the wave particle duality of light and matter, including concepts of
photons and de Broglie wavelength.
Objective:
To understand the dual nature of radiation and matter and apply these concepts
in quantum mechanics.
15. Structure of Atoms and Nuclei
Content:
Exploration of atomic models, quantum numbers, nuclear structure, and
radioactivity.
Objective:
To analyze atomic structure and nuclear processes, understanding fundamental
principles of atomic physics.
16. Semiconductor Devices
Content:
Study of semiconductors, pn junctions, diodes, transistors, and their
applications in electronics.
Objective:
To understand the principles of semiconductor behavior and analyze their
applications in modern electronic devices.
