The Best BITSAT Syllabus for Math and Chemistry in 2025

$BITSAT Syllabus for Math and Chemistry in 2025$ The BITSAT exam is administered using the NCERT syllabus for classes 11 and 12. Masterclass Space offers the 2025 BITSAT syllabus. Candidates must study the chapters and subjects listed in the BITSAT syllabus. The BITSAT Syllabus 2025 is available through Masterclass Space. The whole BITSAT exam syllabus, broken down by chapter, is available here.

Physics Syllabus for BITSAT

1. Measurement & Units

Units (SI units, fundamental and derived units, various systems of units)
Analysis of Dimensions
Accuracy and important numbers
Basic physics measures (physical balance, screw gauge, vernier calipers, etc.)

2. Kinematics

Vector properties
Vectors of position, velocity, and acceleration
Constantly accelerating motion
Motion of projectiles
Uniform circular motion
Motion in relation

3. The Laws of Motion by Newton

Newton's laws (resolution of forces, free body diagram)
Motion on a plane that is inclined
Block motion using pulley systems
Centripetal force in circular motion
Frames that are and are not inertial

4. Momentum and Impulse

Impulse and momentum definition
Momentum conservation 4.3 Collisions
A particle system's momentum
The center of mass

5. Energy and Work

Work performed by an entity
The work-energy theorem and kinetic energy
Strength
Potential energy and conservative forces
Mechanical energy conservation

6. The motion of rotation

An explanation of rotation, including its angular acceleration, velocity, and displacement
Constant angular acceleration while rotating
Theorems of the parallel and perpendicular axes, rotational kinetic energy, and moment of inertia
Angle of momentum and torque
The preservation of rotational momentum
Rolling motion

7. Grasping

Newton's gravitational law
Energy of gravitational potential, escape velocity
Planetary motion, including satellite motion and Kepler's laws

8. Solid and Fluid Mechanics

Flexibility
Archimedes' principle, pressure, and density
Surface Tension and Viscosity
The Theorem of Bernoulli

9. The oscillations

Simple harmonic motion kinematics
Simple and compound pendulums with spring mass systems
Resonance and damped and forced oscillations

10. The waves

Sinusoidal waves that progress
Pipes and strings with standing waves
Wave and beat superposition
The Effect of Doppler

11. Thermodynamics and Heat

Gas kinetic theory
Temperature and thermal equilibrium
Specific heat, Newton's law of cooling, thermal conductivity, and heat transfer—including conduction, convection, and radiation
The first law of thermodynamics, work, and heat
Carnot engine efficiency and performance coefficient, second law of thermodynamics

12. The science of electrostatics

The Law of Coulomb
Discrete and continuous charge distributions in an electric field
The interaction between electrostatic potential and energy
The uses of Gauss's law
A dipole electric
Dielectrics and capacitance (series and parallel capacitors, parallel plate capacitors)

13. Present-Day Electricity

Ohm's law and Joule heating
D.C circuits: Wheatstone bridge, Kirchhoff's rules, series and parallel resistors, and cells
Electrical Resistance (Resistivity, resistance's origin, and its temperature dependency).

14. Current's Magnetic Effect

Applications of Biot-Savart's Law
The uses of Ampere's law
In a magnetic field, the Lorentz force acts on conductors carrying current.
Torque on a current loop, magnetic moment of a current loop, the conversion of a galvanometer into a voltmeter, and an ammeter

15. Induction of Electromagnetics

Eddy currents, Lenz's law, and Faraday's law
Mutual and self-inductance
Generators and transformers
Peak and rms values of the alternating current
Circuits for AC and LCR

16. The field of optics

Refraction and reflection laws
Mirrors and lenses
Optical tools: microscope and telescope
Interference: Young's double slit experiment and Huygen's concept
Interference in thin films
A single slit causes diffraction
Electromagnetic waves and their properties (only qualitative concepts), Electromagnetic spectrum
Polarization: Brewster's law, Malus' law, and states of polarization

17. Current Physics

The photoelectric effect, De Broglie wavelength, and the dual nature of matter and light
Bohr's atomic model and Rutherford's experiment
Spectrum of the hydrogen atom
The radioactivity
Nuclear reactions: energy of binding, fission, and fusion

BITSAT Chemistry Syllabus

1. Conditions of Matter

Measurement: SI units and physical quantities, precision, dimensional analysis, and significant figures.
Chemical reactions: atomic, molecular, and molar masses; Dalton's atomic theory; laws of chemical combination; mole concept; empirical and molecular formulas for percentage composition; balanced chemical equations and stoichiometry
Three states of matter, bonding kinds, melting and boiling points, and intermolecular interactions The state of gas: Ideal behavior, the ideal gas equation, its empirical derivation, the Avogadro number, the critical temperature at which ideal behavior deviates, liquefaction of gases, the van der Waals equation, and gas laws.
Liquid state: surface tension, viscosity, and vapour pressure.
Classification of solid states; crystal systems and space lattices; unit cell in two- and three-dimensional lattices, unit cell density computation for cubic and hexagonal systems; pack tightly; Crystal compositions: Covalent crystals, such as diamond and graphite, and simple AB and AB2 type ionic crystals are metals. A cubic unit cell's voids, atoms per unit cell, Imperfections: non-stoichiometric crystals, point flaws; dielectric, magnetic, and electrical characteristics; Description of amorphous solids in qualitative terms: metal, conductor, semiconductor, insulator, and n- and p-type semiconductor band theory.

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2. Structure of Atoms

Introduction: Subatomic particles; Bohr model and its limits; Hydrogen atom spectrum; Thompson's model and its limitations; Rutherford's picture of the atom and its limitations; Atomic number, isotopes, and isobars.
The hydrogen atom: quantum numbers and wavefunctions, atomic orbitals and their forms (s, p, and d), and spin quantum number; quantum mechanics: wave-particle duality – de Broglie relation, Uncertainty principle.
Pauli exclusion principle: many-electron atoms; Hund's rule, the Aufbau principle, and the electronic arrangement of atoms.
Periodicity: A synopsis of how periodic tables evolved. The current periodic table and periodic law; elements of the following types: s, p, d, and f blocks; Ionization energy, atomic and ionic radii, interatomic radii, electron affinity, electronegativity, and valency are examples of periodic trends. Elements having nuclear numbers higher than 100 and their nomenclature.

3. Chemical Interactions and Molecular Architecture

Ionic bonds and valence electrons: Born-Haber cycles and lattice energy; covalent and polar covalent bond characteristics; and bond parameters.
Molecular Structure: VSEPR model, Lewis image, resonance structures, and molecular forms
Covalent Bond: Valence Bond Theory: Orbital overlap, Directionality of Bonds & Hybridization (merely s, p, and d orbitals), Resonance; Molecular Orbital Theory: Methodology, Orbital Energy Level Diagram, Bond Order, Magnetic Properties for Homonuclear Diatomic Species (qualitative idea only).
The hydrogen bond and dipole moments.

4. Thermodynamics.

Fundamental Ideas: Environment and Systems; Functions of the State; Complex and Wide-ranging Properties; Temperature and Zeroth Law
First Thermodynamic Law: Hess's Law, enthalpies of bond dissociation, combustion, atomization, sublimation, solution, and dilution; thermochemistry; work, internal energy, heat, enthalpy, heat capacities, and specific heats; measurements of ∆U and ∆H; enthalpies of formation, phase transition, ionization, and electron gain
Second Law: Entropy, spontaneous and reversible processes, Gibbs free energy associated with non-mechanical work and spontaneity, standard free energies of formation, free energy change, and chemical equilibrium
Third Law: Overview

5. Equilibria, both chemical and physical

Molarity, Molality, and Mole Fraction as Concentration Units
Solutions: Raoult's law, Vapour Pressure, Solid-Gas Solubility in Liquids, decreased vapour pressure, decreased freezing point, increased boiling point, osmotic pressure, molecular mass measurement, solid solutions, aberrant molecular mass, and van't Hoff factor. Law of mass action and the equilibrium's dynamic character
Equilibria including physical changes (solid-liquid, liquid-gas, solid-gas), surface chemistry, adsorption, Langmuir isotherm, and physical and chemical adsorption. Emulsions and colloids: categorization, preparation, and applications.
Chemical Equilibria: LeChatelier's principle, parameters influencing equilibrium, and equilibrium constants (KP, KC).
Ionic Equilibria: Arrhenius, Lewis, Lowry, and Bronsted bases and their dissociation; strong and weak electrolytes; ionization degree; ionization of water; ionization of polybasic acids; pH; buffer solutions; Henderson equation; titrations of acids and bases; hydrolysis; solubility product of sparingly soluble salts; and the common ion effect.
Effects of Temperature, Pressure, Concentration, Catalysts, and the Significance of G0 and G in Chemical Equilibria on Equilibria.

6. The study of electrochemistry

Redox Reactions: Oxidation number; Redox reaction balancing; Oxidation-reduction reactions (electron transfer idea); cell reactions and electrochemical cells; Secondary cells, dry cells, fuel cells, Gibbs energy change and cell potential, Nernst equation, EMF of galvanic cells, standard electrode potentials, and corrosion and its avoidance.
Electrolytic Conduction: Electrolytic Conductance; Molar and specific conductivities; differences in conductivity with concentration; the use of Kohlrausch's Law, Electrolysis, Faraday's electrolysis laws, electrolysis and electrode potential, commercial chemical production, NaOH, Na, and Al.

7. Kinetics of Chemicals

Aspects of Kinetics: Half-lives and integrated rate expressions for zero and first order reactions; order and molecularity of the reaction; rate and rate expression of a reaction; rate constant.
A Factor Influencing Reaction Rate: Activation energy, temperature dependence of the rate constant concept of collision theory (a basic idea without any mathematical treatment), reactant and catalyst concentration, and particle size.
Surface Chemistry: Adsorption, including physisorption and chemisorption; variables influencing gas adsorption on solids; Selectivity, activity, and homogeneous and heterogeneous catalysis: Enzyme catalysis, colloidal state: differentiation between suspensions, colloids, and real solutions; lyophillic and lyophobic multimolecular and macromolecular colloidal properties; electrophoresis, coagulations, Brownian movement, and Tyndall effect; several kinds of emulsions.

8. Hydrogen and s-block elements
9. p- d- and f-block elements
10. Principles of Organic Chemistry and Hydrocarbons
11. Stereochemistry
12. Organic Compounds with Functional Groups Containing Oxygen and Nitrogen
13. Biological, Industrial, and Environmental Chemistry 14. Theoretical Principles of Experimental Chemistry
Conclusion

More information on the best BITSAT Syllabus 2025 can be found at www.masterclassspace.com. Masterclass Space offers the 2025 BITSAT syllabus.