NEET Physics 2026

Master the fundamentals of measurement, including SI units, dimensional analysis, and its applications. Learn to identify and calculate errors in measurements, least count, and significant figures.

Explore motion in a straight line and in a plane. Topics include position-time graphs, average speed, instantaneous velocity, uniform and non-uniform accelerated motion, scalars, vectors, and projectile motion.

Understand the core principles of dynamics including Newton’s Three Laws of Motion, momentum, and impulse. Learn about the law of conservation of linear momentum, static and kinetic friction, and the dynamics of uniform circular motion on level and banked roads.

Study the work done by constant and variable forces, kinetic and potential energy, and the work-energy theorem. This unit also covers the conservation of mechanical energy, vertical circular motion, and elastic/inelastic collisions.

Focus on the center of mass of rigid bodies, torque, and angular momentum. Learn about the moment of inertia, the radius of gyration, and the application of parallel and perpendicular axes theorems.

Examine the Universal Law of Gravitation, acceleration due to gravity (g), and its variation with altitude and depth. Study Kepler’s laws of planetary motion, escape velocity, and the energy of satellites.

Learn about elastic behavior, stress-strain relationships, Hooke’s Law, and various moduli. Explore fluid mechanics through Pascal’s Law, Bernoulli’s principle, viscosity, surface tension, and thermal properties like specific heat and calorimetry.

Understand thermal equilibrium and the Zeroth, First, and Second Laws of Thermodynamics. Topics include isothermal and adiabatic processes, as well as reversible and irreversible processes.

Study the equation of state for a perfect gas, kinetic theory assumptions, and the concept of pressure. Learn about degrees of freedom, the law of equipartition of energy, and the mean free path.

Analyze periodic motion, Simple Harmonic Motion (S.H.M.), and the energy involved in oscillations. Explore wave motion, including longitudinal and transverse waves, the principle of superposition, and standing waves in strings and pipes.

Examine electric charges, Coulomb’s law, and electric fields due to various distributions. Study electric flux, Gauss’s law, electric potential, and the behavior of capacitors and dielectrics.

Understand electric current, drift velocity, Ohm’s law, and V-I characteristics. Learn about the combination of resistors, Kirchhoff’s laws, and measurement tools like the Wheatstone bridge and Metre Bridge.

Study the Biot-Savart and Ampere laws, and the force on moving charges in magnetic fields. Explore the properties of bar magnets, magnetic dipoles, and the classification of para-, dia-, and ferromagnetic substances.

Learn about Faraday’s and Lenz’s laws, self and mutual inductance, and eddy currents. Study alternating currents (AC), peak and RMS values, LCR circuits, resonance, and the functioning of transformers.

Understand displacement current and the characteristics and transverse nature of EM waves. Explore the electromagnetic spectrum—from radio waves to gamma rays—and their practical applications.

Analyze ray optics, including spherical mirrors, the mirror formula, and lens maker’s formula. Dive into wave optics to learn about Huygens’ principle, interference (Young’s double-slit), diffraction, and polarization.

Study the photoelectric effect, Hertz and Lenard’s observations, and Einstein’s photoelectric equation. Learn about the de Broglie relation and the wave nature of particles.

Explore atomic models (Rutherford and Bohr) and the hydrogen spectrum. Study the composition of the nucleus, mass-energy relations, binding energy, and the processes of nuclear fission and fusion.

Understand semiconductors, I-V characteristics of P-N junction diodes, and their use as rectifiers. Learn about LEDs, solar cells, Zener diodes as voltage regulators, and the fundamentals of Logic Gates.

Gain practical familiarity with 18 key experiments, including using Vernier calipers and screw gauges, determining Young’s modulus, and plotting characteristic curves for diodes.