CBSE Class 12 Physics Syllabus

CBSE Class 12 Physics syllabus contains marking scheme and chapter wise topics including theory and practical syllabus. The class 12 Physics is the major subjects for students who are planning to take the career in engineering. This page contains the basic information about the syllabus of class 12 physics.

Byju’s also provides CBSE syllabus for class 6 to class12 in a detailed manner along with marking scheme. Along with syllabus CBSE Sample Papers, RD Sharma solutions, NCERT Solutions, chapter wise test series and important questions are provided to help students prepare well for their academic life.

Marking Scheme

Unit Chapter / Topic Marks
I Electrostatics 15
Chapter-1: Electric Charges and Fields
Chapter-2: Electrostatic Potential and Capacitance
II Current Electricity
Chapter-3: Current Electricity
III Magnetic Effect of Current & Magnetism 16
Chapter-4: Moving Charges and Magnetism
Chapter-5: Magnetism and Matter
IV Electromagnetic Induction & Alternating Current
Chapter-6: Electromagnetic Induction
Chapter-7: Alternating Current
V Electromagnetic Waves 17
Chapter-8: Electromagnetic Waves
VI Optics
Chapter-9: Ray Optics and Optical Instruments
Chapter-10: Wave Optics
VII Dual Nature of Matter 10
Chapter-11: Dual Nature of Radiation and Matter
VIII Atoms & Nuclei
Chapter-12: Atoms
Chapter-13: Nuclei
IX Electronic Devices 12
Chapter-14:  Semiconductor  Electronics
X Communication Systems
Chapter-15: Communication Systems
Total 70

Electric Charges; Conservation of charge, Coulomb’s law-force between two point charges, forces between multiple charges; superposition principle and continuous charge distribution.Electric field, electric field due to a point charge, electric field lines, electric dipole, electric field due to a dipole, torque on a dipole in uniform electric fleld.

Electric flux, statement of Gauss’s theorem and its applications to find field due to infinitely long straight wire, uniformly charged infinite plane sheet and uniformly charged thin spherical shell (field inside and outside).

Electric potential, potential difference, electric potential due to a point charge, a dipole and system of charges; equipotential surfaces, electrical potential energy of a system of two point charges and of electric dipole in an electrostatic field.Conductors and insulators, free charges and bound charges inside a conductor. Dielectrics and electric polarisation, capacitors and capacitance, combination of capacitors in series and in parallel, capacitance of a parallel plate capacitor with and without dielectric medium between the plates, energy stored in a capacitor.

Electric current, flow of electric charges in a metallic conductor, drift velocity, mobility and their relation with electric current; Ohm’s law, electrical resistance, V-I characteristics (linear and non-linear), electrical energy and power, electrical resistivity and conductivity. Carbon resistors, colour code for carbon resistors; series and parallel combinations of resistors; temperature dependence of resistance.Internal resistance of a cell, potential difference and emf of a cell,combination of cells in series and in parallel. Kirchhoff’s laws and simple applications. Wheatstone bridge, metre bridge.

Potentiometer – principle and its applications to measure potential difference and for comparing emf of two cells; measurement of internal resistance of a cell.

Concept of magnetic field, Oersted’s experiment.Biot – Savart law and its application to current carrying circular loop.

Ampere’s law and its applications to infinitely long straight wire. Straight and toroidal solenoids, Force on a moving charge in uniform magnetic and electric fields. Cyclotron.

Force on a current-carrying conductor in a uniform magnetic field. Force between two parallel current-carrying conductors-definition of ampere. Torque experienced by a current loop in uniform magnetic field; moving coil galvanometer-its current sensitivity and conversion to ammeter and voltmeter.

Current loop as a magnetic dipole and its magnetic dipole moment. Magnetic dipole moment of a revolving electron. Magnetic field intensity due to a magnetic dipole (bar magnet) along its axis and perpendicular to its axis. Torque on a magnetic dipole (bar magnet) in a uniform magnetic field; bar magnet as an equivalent solenoid, magnetic field lines; Earth’s magnetic field and magnetic elements.Para-, dia- and ferro – magnetic substances, with examples. Electromagnets and factors affecting their strengths. Permanent magnets.

Electromagnetic induction; Faraday’s laws, induced emf and current; Lenz’s Law, Eddy currents.Self and mutual induction.

Alternating currents, peak and rms value of alternating current/voltage; reactance and impedance; LC oscillations (qualitative treatment only), LCR series circuit, resonance; power in AC circuits, wattless current.AC generator and transformer.

Basic idea of displacement current, Electromagnetic waves, their characteristics, their transverse nature (qualitative ideas only).Electromagnetic spectrum (radio waves, microwaves, infrared, visible, ultraviolet, X-rays, gamma rays) including elementary facts about their uses.

Ray Optics: Reflection of light, spherical mirrors, mirror formula. Refraction of light, total internal reflection and its applications, optical fibres, refraction at spherical surfaces, lenses, thin lens formula, lensmaker’s formula. Magnification, power of a lens, combination of thin lenses in contact combination of a lens and a mirror. Refraction and dispersion of light through a prism.Scattering of light – blue colour of sky and reddish apprearance of the sun at sunrise and sunset.

Optical instruments: Microscopes and astronomical telescopes (reflecting and refracting) and their magnifying powers.

Wave optics: Wave front and Huygen’s principle, relection and refraction of plane wave at a plane surface using wave fronts. Proof of laws of reflection and refraction using Huygen’s principle. Interference Young’s double slit experiment and expression for fringe width, coherent sources and sustained interference of light. Diffraction due to a single slit, width of central maximum. Resolving power of microscopes and astronomical telescopes. Polarisation, plane polarised light Brewster’s law, uses of plane polarised light and Polaroids.

Dual nature of radiation. Photoelectric effect, Hertz and Lenard’s observations; Einstein’s photoelectric equation-particle nature of light.Matter waves-wave nature of particles, de Broglie relation. Davisson-Germer experiment (experimental details should be omitted; only conclusion should be explained).

Alpha-particle scattering experiment; Rutherford’s model of atom; Bohr model, energy levels, hydrogen spectrum.

Composition and size of nucleus, atomic masses, isotopes, isobars; isotones. Radioactivityalpha, beta and gamma particles/rays and their properties; radioactive decay law.Mass-energy relation, mass defect; binding energy per nucleon and its variation with mass number; nuclear fission, nuclear fusion.

Energy bands in conductors, semiconductors and insulators (qualitative ideas only)Semiconductor diode – I-V characteristics in forward and reverse bias, diode as a rectifier;

Special purpose p-n junction diodes: LED, photodiode, solar cell and Zener diode and their characteristics, zener diode as a voltage regulator.

Junction transistor, transistor action, characteristics of a transistor and transistor as an amplifier (common emitter configuration), basic idea of analog and digital signals, Logic gates (OR, AND, NOT, NAND and NOR).

Elements of a communication system (block diagram only); bandwidth of signals (speech, TV and digital data); bandwidth of transmission medium. Propagation of electromagnetic waves in the atmosphere, sky and space wave propagation, satellite communication. Need for modulation, amplitude modulation and frequency modulation, advantages of frequency modulation over amplitude modulation. Basic ideas about internet, mobile telephony and global positioning system (GPS).


Practise This Question

You are in outer space at point A and you are “falling” towards Jupiter. But lucky for you, you’re “falling” at a speed of ‘v’ which is higher than the escape velocity of Jupiter’s gravitational field at a distance ‘R’ as shown in the figure. Your prayers to the Old Gods and the New seem to be working because luck is on your side once again. You don’t fall directly onto the planet but go around it and away from it because of your escape velocity. When you reach point B, what is your speed(v’) ? (Assume the only force that acted on you is Jupiter’s gravitational pull. Also assume Jupiter is stationary.)