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1. Mechanics
1.1.1 Conservation Laws Newtons Laws Equation of Motion
1.1.2 Work Energy Theorem
1.1.3 Conservative and Non- Conservative Force 1
1.2.1 Motion of Object near the surface of Earth
1.2.2 Linear Restoring Force
1.2.3 Potential Energy Curve
2.1.1 Principle of Conservation of Linear Momentum for system of n-particles
2.1.2 Center of Mass
2.1.3 Inelastic Collision
2.1.4 One Dimensional Elastic Collision
2.1.5 Two Dimensional Elastic Collision
2.2.1 Rocket - System of Variable Mass 1
2.3.1 Motion of Center of Mass
2.3.2 Reduction of Two Body Problem into One Body Problem
3.1.1 Escape Velocity 2 and Orbital Velocity
3.1.2 Gravitational Field Intensity and Escape Velocity 1
3.1.3 Gravitational Potential and Potential Energy 1
3.1.4 Gravitational Potential and Potential Energy 2
3.1.5 Gravitational Ptential and Field due to Spherical Shell 1
3.1.6 Gravitational Ptential and Field due to Spherical Shell 2
3.1.7 Kepler Law of Planetary Motion 1
3.1.8 Kepler Law of Planetary Motion 2
4.1 Theorem on Moment of Inertia by parallel axis theorem
4.2 Moment of Inertia Due to Sperical Shell
4.3 Moment of Inertia Due to Solidl Shell
4.4 Moment of inertia Due to solid cylinder
4.5 Theorem on Moment of Inertia by perpendicular axis theorem
4.6 Kinetic Energy of Rotation
4.7 Reduction of Two Body Problem into One Body Problem
5.1 Differential Euation of Harmonic Osciliator & Its solution
5.1.1 Differential Euation of Harmonic Osciliator & Its solution 2
5.2.1 Simple Pendulam
5.2.2 Compound Pendulum
5.2.3 Bar pendulum
5.2.4 Time period Compound Pendulum
5.3 N-Coupled Osciliator
5.4 Helmholtz resonator
5.5 Damped harmonic oscillator
5.6 Differential Equation of Damped Harmonic Ossicilator
5.7 Engery Dissipation in Damped harmonic oscillator
5.7.1Engery Dissipation in Damped harmonic oscillator 2
5.8 Forced harmonic Ossicialation
5.8.1 Forced Harmonic Ossciliator of Quality Factor
5.9 Power Absorption
5.9.1 Sharpness of Resonance
5.9.2 Velocity Resonance
6.1 Wave Motion & Wave equation
6.2 Wave equation 1
6.3 Energy Density of Progressive wave
6.4 Average kinetic & potential Energy of Progressive wave
6.5 Intensity of wave & Sperical wave
6.6 Modes of Vibration in Stretched Srtring
6.7 Longitudinal Wave in Rod
6.7.1 Longitudinal wave in gaseous medium
6.8 Flow of energy in stationary waves
7.1 Elasticity
7.2 Relations connecting various elastic constants
7.2.1 Relations connecting various elastic constants
7.3 Angle of Twist and Shear
7.4 Twisting couple on a cylindrical rod or wire
7.5 Workdone in Twisting Cylinder wire & rod
7.6 Bending of Beams
7.6.1 Expression for bending moment
7.7 Cantilever
7.7.1 Cantilever
7.7.2 Cantilever 3
7.8 Elasticity ( When Weight of beam is Ineffective)
7.8.1 Elasticity(When Weight of the beam is effective)
7.8.2 Elasticity(When Weight of the beam is effective)
7.9 Elasticity( When Beam is Uniformly Loaded)
8.1 Viscocity
8.1.1 Viscocityt
8.2 Effect of Temperatur on Viscocity
8.3 Flow of Liquid in a Capillary tube by Poiseuille's equation
8.4 Capillaries in Series & Parallel
8.5 Capillaries in parallel
8.6 Equation in Continuity
8.7 Energy possed By Flowing Liquid
8.8 Bernoulli es Theorem
8.8.1 Bernoulli-es Theorem
Marks Scheme 1
Marks Scheme 2
2. Thermodynamics
1.1 Fundamental Concept of Thermodynamics
1.2 Fundamental Concept of Thermodynamics
1.3 Zeroth Law of Thermodynamics
1.4 Concept of Quari-Statiscal Process
1.5 Harmonic Oscillator
1.6 Harmonic Oscillator part 2
1.7 Harmonic Oscillator part 3
1.8 Law of conservation of momentum
1.9 Law of conservation of momentum part 2
1.10 Vector Concept
1.11 Vector Concept 2
2.1 Second Law of Thermodynamics
2.2 Carnot cycle
2.3 Carnot theorem
2.4 Third law of Thermodynamic Relations
3.1 Second latent heat equation, thermodynamics relations
4.1 Production of low temperature
4.2 Boyls temperature
4.3 Nummerical of production of low temperature
5.1 Mean free path, momentum ,viscosity ,diffusion transport
5.2 Browinian motion
5.3 Nummerical of transport phenomenon
6.1 Concept of real gas , joule thomson expansion ,vaander waal's equations
7.1 Introduction of radiation
7.2 Solar radiation
7.3 Average energy
7.4 Average Energy of Plank's Oscillator
7.5 Stefan law proof
7.5.1 Numerical on Radiation
7.5.2 Numerical for radiation
3. Statiscal Physics
1.1 Concept of microsate and macrostate
1.2 Quantum Phase Space
1.3 Degree of freedom & Equal Portion Energy
1.4 Numerical Degree of freedom & Equal Portion Energy
2.1 Quantum Statistical Physics
2.2 Fermi-Dirae Statstics
2.3 Result Of Three Statistics
4. Electricity & Magnetism
1.1 Electricity & Magnetism
1.2. Dell Operator & Nabla Operator
1.3. Scaler Gradient
1.4. Numerical on Scalar Gradient
1.5. line integral
1.6. Surface integral
1.7. Divergence
1.8. Physical meaning of Divergence
1.8.1 Physical meaning of Divergence
1.8.1 physical meaning of divergence 1(No need to upload)
1.8.1 physical meaning of divergence 2(No need to upload)
1.8.2 physical meaning of divergence 3(No need to upload)
1.9. Curl of vector function
1.10. Physical Significance of Curl
1.11. Guass-Divergence Theorm
1.11.1 Guass-Divergence Theorm
1.12. Stokes Thorem
1.13. Numericals on Curl & Vector Identities
1.14. Conservative Field & Green's Theorm
2.1. Columb's Law
2.1.1 Columb's Law
2.2. Electric Field Intensity
2.3. Electric Potential
2.3.1 Electric Potential
2.4. Electric Field & Potential due to Dipole
2.4.1 Electric Field & Potential due to Dipole
2.5. Electric Dipole in External Field
2.6. Numerical on Electric Dipole
2.7. Concept of Solid Angle
2.8. Gauss Law & Its differential Form
2.9. Poissons & laplace Equation in Electrostatics
2.10. Application of Gauss Law
2.10.1 Application of Gauss Law
2.10.2 Electro static Pressure on the Surface of Charged Conductor
2.10.3 Application on Guass law on the surface of charged conductor
2.10.4 Application of Guass Law
2.11. Numericals on Guass Law
2.11.1 Numericals on Guass Law
2.12. Electric Field & Potential Due to Line Charge
2.12.1 Electric Field & Potential Due to Line Charge
2.13. Electric Field & Potential Due to Charged Disc
2.13.1 Electric Field & Potential Due to Charged Disc
2.13.2 Problem on Electric Field and potentials & Concept of Electric Image
2.13.3 Electric Image
2.13.4 Point Charge Near Grounded Conducting Plane using Method of Image
2.13.5 Point Charge Near Grounded Conducting Plane using Method of Image
2.13.6 Point Charge Near Grounded Conducting Sphere using Method of Image
2.13.7 Point Charge Near Grounded Conducting Sphere using Method of Image
2.13.8 Point Charge Near Grounded Conducting Sphere using Method of Image (Numerical)
2.13.9 Numerical on Electric Field
3.1. Dieletric & its types with Polarization Concept
3.1.1 Dieletric Polarization
3.2 Clausius-Mosotti Relation
3.2. 1. Guass Law in Dieletric
3.2.2 Electric Susceptibility & Atomic Polarisability
3.3 Clausius-Mosotti Relation
3.3.1 Clausius-Mosotti Relation
3.3.2 Numericals on Clausius-Mosotti Relation
3.4 Langevin-Debye Equation
3.4.1 Langevin-Debye Equation
3.4.2 Langevin-Debye Equation
3.5 Boundary Condition on Field Vectors
3.5.1 Boundary Condition on Field Vectors
4.1. Orested Discovery
4.1.1 Lorentz force
4.1.2 Biotsavart Law
4.1.3 Comparision of Electrostatic & Magnetic Force
4.1.4 Magnetic Field Due to Straight Conductor from Biot-Savart Law
4.1.5 Magnetic Field at Center of Circular Coil from Biot-Savart Law
4.1.5.1 Magnetic Field Due to Straight Conductor from Biot-Savart Law
4.1.6 Magnetic Field at Axis of Circular Coil from Biot-Savart Law
4.1.7 Magnetic Field at Axis of Circular Coil from Biot-Savart Law
4.1.8 Magnetic Field at Axis of Solenoid from Biot-Savart Law
4.1.9 Force between Two Parallel Current Carrying Conductors
4.1.10 Force between Two Parallel Current Carrying Conductors
4.2. Show magnetic Field is Soleniodal
4.2.1 Numerical of Charged Particles Inside Magnetic Field
4.2.2 Numericals on Magnetostatics
4.3. Ampere's Law
4.3.1 Applications of Ampere's Law
4.4. Magnetic Vector Potential
4.5. Poisson Equation in Magneto statics & Magnetic Scalar Potential
5.2. Langevin Therory of Diamagnetism
5.3. Langevin Thoery of Paramagnetism
5.4. Ferromagnetic Substances
5.5. Magnetic Hyterisis
6.1. Concept of Magnetic Flux with Numerical
6.2. Faradays Law of Electromagnetic Induction
6.3. Self Induction & its Calculation n Using Soleniod
6.3.1 Self Induction of Torrid & Mutual Induction
6.3.2 Reciprocity Thorem of Mutual Induction
6.3.3 Relation Between Self Induction & Mutual Induction
6.3.4 Numerical on Self Induction & Mutual Induction
6.4. Energy Stored in Inductive Circuit
7.1. Growth of Current in L-R Circuit
7.1.1 Decay of Current in L-R Circuit
7.1.2 Numericals on Growth & Decay of Current in L-R Circuit
7.2. Charging of Capacitor Through Resistance( R-C Circuit)
7.2.1 Discharging of Capacitor Through Resistance( R-C Circuit)
7.2.2 Discharge of Capacitor Through Inductor (L-C Circuit)
7.2.3 Numericals on Charging & Discharging of Capacitors
8.1. Complex Representation of AC & R Circuit
8.1.2 L-circuit
8.1.3 C-circuit
8.1.4 Power Factor
8.1.5 L-R Circuit
8.1.6 Series L-C-R Circuit
8.1.6.1 Series L-C-R Circuit
8.1.7 Sharpness of Resonance
8.1.8 Quality factor of CKT
8.2 Numerical on A.C
8.2.1 Numerical On AC
9.0 Maxwell's Equations
9.0.1 Maxwells Fourth Equations
9.1 Physical Significance in Displacement Current
9.2 Electromagnetic Field in Free Space
9.3 Electromagnetic waves in non-Conducting Isotropic Medium
9.4 Electromagnetic waves in Conducting Medium
9.5 Poynting Vector