48:50

Lecture 64 : Gamow's Theory of Alpha Decay | Geiger -Nuttall Law

33:18

Lecture 63 : Quantum Tunneling

54:43

Lecture 62 : The Potential Barrier when E is less than V₀

01:01:41

Lecture 61 : The Potential Barrier when E is more than V₀

35:15

Lecture 60 : The Step Potential when E is more than V₀

29:26

Lecture 59 : The Step Potential when E is less than V₀

51:06

Lecture 58 : Finite Potential Well (Second Type) - Scattering State Solutions.

42:17

Lecture 57 : Finite Potential Well (Second Type) - Bound State Solutions

01:02:55

Lecture 56 : Finite Potential Well (First Type) - Bound State & Unbound State Solutions.

31:47

Lecture 55 : Three-Dimensional Infinite Square Well Potential

35:59

Lecture 54 : The Particle in a Box - Infinitely Deep Symmetric Potential Well

50:13

Lecture 53 : The Particle in a Box - Infinite Asymmetric Square Well Potential

33:36

Lecture 52 : Free Particle in One-dimension

25:30

Lecture 51 : Time Evolution of the Expectation Value | Constants of Motion | Ehrenfest Theorem

19:01

Lecture 50 : Compatible & Incompatible Observables | Common Eigenfunctions of Commuting Operators

25:18

Lecture 49 : Hermitian Operator | Hermitian Conjugate | And their Properties

16:34

Lecture 48 : Expectation Values of Dynamic Variables

15:35

Lecture 47 : Degenerate | Non-Degenerate | Orthonormal Eigenfunctions

21:18

Lecture 46 : Linear and Antilinear Operators | Parity Operator

36:02

Lecture 45 : Angular Momentum Operators and their Commutation Relations | Ladder Operators

19:44

Lecture 44 : Commutation Relations between Position, Hamiltonian and Momentum Operators

28:53

Lecture 43 : Commutators and their Properties | Jacobi Identity.

19:15

Lecture 42 : Properties of Quantum Mechanical Operators

32:27

Lecture 41 : Quantum Mechanical Operators | Dynamical Variables (Observables) | Eigenvalue Equation

31:53

Lecture 40 : Probability Current Density | Continuity Equation

23:52

Lecture 39 : ACCEPTABLE SOLUTIONS OF The WAVE FUNCTION OR PROPERTIES OF THE WAVE FUNCTION

28:20

Lecture 38 : Time Independent Schrödinger Equation | Solution of Time Dependent Schrödinger Equation

36:11

Lecture 37 : Time Dependent Schrodinger Equation

25:05

Lecture 36 : Mass of π-Meson | Zero point energy of Harmonic Oscillator

19:31

Lecture 35 : Non-existence of the Electron inside the Nucleus

18:42

Lecture 34 : The Ground State Energy & Radius of H-Atom | Consequences of the Uncertainty Principle

17:54

Lecture 33 : The Path of an Object | Zero - Point Energy | Consequences of the Uncertainty Principle

19:12

Lecture 32 : Double Slit Interference Experiment - Illustration Uncertainty Principle

11:59

Lecture 31 : Single Slit Diffraction Experiment - Illustration for Uncertainty Principle

25:37

Lecture 30 : Gamma Ray Microscope Experiment | Thought Experiment

33:57

Lecture 29 : Heisenberg Uncertainty Principle

32:27

Lecture 28 : The Wave Packet | Motion of Wave Packet | Reciprocity Relation

21:57

Lecture 27 : Born's Interpretation of the Wave Function | Dimensions of wave function

21:36

Lecture 26 : Relation Between Phase Velocity & Group Velocity | Dispersion Relation

24:30

Lecture 18 : Spectral Lines in a H-Like Atom | Bohr's Correspondence Principle.

43:07

Lecture 17 : Bohr's Model of An Atom

28:26

Lecture 25 : Concept of Group Velocity

23:11

Lecture 24 : Concept of Phase Velocity or Wave Velocity.

25:48

Lecture 23 : Quantum view of Particles and Waves

23:58

Lecture 22 : Classical view of Particles and Wave.

40:21

Lecture 24 : Four Level Laser Rate Equation

32:50

Lecture 21 : Davisson - Germer Experiment | G.P Thomson Experiment

33:01

Lecture 23 : Three Level Laser Rate Equation

13:14

Lecture 20 : De Broglie Wavelength in terms of Kinetic Energy and Accelerating Potential.

40:16

Lecture 19 : De Broglie's Hypothesis - Matter Waves | UPSC IAS Physics Optional

32:00

Lecture 16 : Pair Production | Pair Annihilation.

29:18

Lecture 15 : Compton Scattering | Relation between θ & ϕ | Kinetic Energy of the Recoil Electron

30:00

Lecture 14 : Derivation of Compton Shift | Limitation of Compton Effect.

25:13

Lecture 13 : Theory of Compton Effect

19:07

Lecture 12 : Einstein's Photoelectric Equation

38:58

Lecture 11 : Introduction to Photoelectric Effect

11:16

Lecture 10 : Derivation of Wien's Displacement Law Using Planck's Radiation Law

12:06

Lecture 09 : Derivation of Stefen-Boltzamann Law Using Planck's Radiation Law

09:47

Lecture 08 : Derivation of Rayleigh-Jeans Law & Wien's Energy Distribution Law Using Planck's Law

20:55

Lecture 07 : Planck's Quantum Hypothesis | Derivation of Planck's Radiation Law