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Mod-06 Lec-20 The Two Body Problem

Mod-08 Lec-30 Angular Momentum Problem (contd.)

Mod-06 Lec-19 The Hydrogen Atom Problem

Mod-08 Lec-29 Angular Momentum Problem using Operator Algebra

Mod-05 Lec-18 The Angular Momentum Problem (Contd.)

Mod-07 Lec-28 Coherent State and Relationship with the Classical Oscillator

Mod-10 Lec-42 Time Independent Perturbation Theory (Contd.2)

Mod-05 Lec-17 The Angular Momentum Problem

Mod-07 Lec-27 The Linear Harmonic Oscillator: Coherent State

Mod-10 Lec-40 Time Independent Perturbation Theory

Mod-09 Lec-35 The JWKB Approximation

Mod-03 Lec-10 Linear Harmonic Oscillator

Mod-07 Lec-25 Dirac's Bra and Ket Algebra : The Linear Harmonic Oscillator

Mod-02 Lec-05 Physical Interpretation of The Wave Function

Mod-04 Lec-15 The 1-Dimensional Potential Wall & Particle in a Box

Mod-09 Lec-39 The JWKB Approximation: Justification of the Connection Formulae

Mod-08 Lec-34 Clebsch Gordon Coefficients

Mod-07 Lec-24 Dirac's Bra and Ket Algebra

Mod-02 Lec-09 On Eigen Values and Eigen Functions of the 1 Dimensional..,

Mod-02 Lec-04 The Free Particle

Mod-04 Lec-14 Tunneling through a Barrier

Mod-09 Lec-38 The JWKB Approximation: Tunneling Probability Calculations and Applications.

Mod-08 Lec-33 Addition of Angular Momentum: Clebsch Gordon Coefficient

Mod-06 Lec-23 3d Oscillator & Dirac's Bra and Ket Algebra

Mod-02 Lec-08 Interference Experiment & The Particle in a Box Problem

Mod-01 Lec-03 Dirac Delta Function & Fourier Transforms

Mod-03 Lec-13 Linear Harmonic Oscillator (Contd3.)

Mod-09 Lec-37 The JWKB Approximation: Use of Connection Formulae

Mod-08 Lec-32 The Larmor Precession and NMR Spherical Harmonics using Operator Algebra

Mod-06 Lec-22 Two Body Problem: The Diatomic molecule (contd.)

Mod-02 Lec-07 The Free Particle (Contd.)

Mod-01 Lec-02 Basic Quantum Mechanics II: The Schrodinger Equation

Mod-03 Lec-12 Linear Harmonic Oscillator (Contd2.)

Mod-10 Lec-41 Time Independent Perturbation Theory (Contd.1)

Mod-09 Lec-36 The JWKB Approximation: Use of Connection Formulae to solve Eigen value Prob

Mod-08 Lec-31 Pauli Spin Matrices and The Stern Gerlach Experiment

Mod-07 Lec-26 The Linear Harmonic Oscillator using Bra and Ket Algebra (contd.)

Mod-06 Lec-21 TheTwo Body Problem: The Hydrogen atom, The Deutron

Mod-04 Lec-16 Particle in a Box and Density of States

Mod-03 Lec-11 Linear Harmonic Oscillator (Contd1.)

Mod-02 Lec-06 Expectation Values & The Uncertainty Principle

Mod-01 Lec-01 Basic Quantum Mechanics I: Wave Particle Duality

Description:

Instructor: Professor Ajoy Ghatak, Department of Physics, IIT Delhi. You will learn Basic mathematical preliminaries: Dirac Delta function and Fourier Transforms. Wave particle duality, one- and three- dimensional Schrodinger equation. The free particle problem in one dimension. Wave Packets and Group velocity. One-dimensional problems: Potential well of infinite and finite depths, the linear harmonic oscillator. Angular Momentum and rotation. Three-dimensional Schrodinger equation: Particle in a box with applications to the free electron model. Particle in a spherically symmetric potential problem. The hydrogen atom and the deuteron. (A numerical method to obtain solutions of the Schrodinger equation will also be discussed and a software to understand basic concepts in quantum mechanics will also be demonstrated). Dirac's bra - ket algebra; Linear Harmonic Oscillator problem using bra - ket algebra, creation and annihilation operators, transition to the classical oscillator, Coherent states. The angular momentum problem, using bra - ket algebra, ladder operators and angular momentum matrices. The Stern Gerlach and magnetic resonance experiments. Addition of Angular Momenta and Clebsch-Gordan coefficients. Perturbation Theory with applications; The JWKB approximation with applications; Scattering Theory: Partial Wave Analysis. Read more

Quantum Mechanics and Application

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#Science #Physics #Quantum Mechanics #Angular Momentum #Perturbation Theory

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