NPTEL : NOC:Time Dependent Quantum Chemistry (Chemistry and Biochemistry)

Co-ordinators : Prof. Atanu Bhattacharya


Lecture 1 - Introduction to TDSE

Lecture 2 - Solution to TDSE, Stationary and Non-stationary States

Lecture 3 - Electron and Vibrational Superposition States

Lecture 4 - Optical Analogy to Quantum Superposition

Lecture 5 - Introdution to Python Programming

Lecture 6 - Simple Computation with Python Programming

Lecture 7 - Plotting Graph with Python Programming

Lecture 8 - Meaning of Probability Density

Lecture 9 - Time Evolution of Normalization Constant

Lecture 10 - Expectation Value and its Time Evolution

Lecture 11 - Equation of Continuity

Lecture 12 - Bohmian Mechanics

Lecture 13 - Bohmian Mechanics and Standard Interpretation

Lecture 14 - Grid Representation of Wavefunction

Lecture 15 - Normalizing the Discretized Wavefunction and Finding Expectation Value

Lecture 16 - Plane Matter Wave and Wavepacket

Lecture 17 - Wavepacket

Lecture 18 - Stationary Gaussian Wavepacket

Lecture 19 - Travelling Gaussian Wavepacket

Lecture 20 - General Form of the Gaussian Wavepacket

Lecture 21 - Fourer Transform of a wavefunction

Lecture 22 - x-grid to k-grid

Lecture 23 - Fourier Transform using fft

Lecture 24 - Hilbert Space and Its Properties

Lecture 25 - Basis Set Approach to Quantum Mechanics

Lecture 26 - Matrix Algebra

Lecture 27 - Eigenvalue and Eigenfunction

Lecture 28 - Matrix Representation of Operators

Lecture 29 - Matrix Representation of Hamiltonian Operator

Lecture 30 - Python Tutorial 4 (Eigenvalue and Eigenfunction)

Lecture 31 - Python Tutorial 4 (Eigenvalue and Eigenfunction)

Lecture 32 - Time Evolution Operator

Lecture 33 - Split Operator Metho

Lecture 34 - Numerical Implementation of Split Operator Method

Lecture 35 - Wavepacket Dynamics under zero interaction potential

Lecture 36 - Wavepacket Dynamics under zero interaction potential (Continued...)

Lecture 37 - Wavepacket Dynamics under linear interaction potential

Lecture 38 - Quantum Adiabatic Theory

Lecture 39 - Formal Derivation of Quantum Adiabat

Lecture 40 - Geometric Phase and Dynamical Phase

Lecture 41 - Nonradiative Transition - Part 1

Lecture 42 - Nonradiative Transition - Part 2

Lecture 43 - Nonradiative Transition

Lecture 44 - Quantum Dissipative Dynamics

Lecture 45 - Quantum Dissipative Dynamics

Lecture 46 - Formal Derivation of Dissipative Quantum Dynamics

Lecture 47 - Classical Description of Light

Lecture 48 - Vector and Scalar Potential

Lecture 49 - Vector and Scalar Potential

Lecture 50 - Master Equation of Light

Lecture 51 - Hamiltonian for Light-Atom Interaction

Lecture 52 - Hamiltonian for Light-Atom Interaction

Lecture 53 - Absorption and Stimulated Emission

Lecture 54 - Absorption and Stimulated Emission

Lecture 55 - Time Correlation Function

Lecture 56 - Fourier Transform of Time Correlation Function