Lecture 1 - Introduction to Statistical Thermodynamics
Lecture 2 - Postulates and Boltzmann Distribution
Lecture 3 - Properties of Canonical Partition Function
Lecture 4 - Canonical Partition Function and Thermodynamic Properties
Lecture 5 - Thermodynamic Properties of Ideal Monoatomic Gases
Lecture 6 - Monoatomic Gases and Gibbs Entropy Equation
Lecture 7 - Energy Fluctuations for Monoatomic Gases
Lecture 8 - Partition Function for Diatomic Gases
Lecture 9 - Vibrational Partition Function
Lecture 10 - Partition Function for Ideal Polyatomic Gas
Lecture 11 - Normal Mode Analysis
Lecture 12 - Illustrations
Lecture 13 - Non-reacting Ideal Gas Mixture
Lecture 14 - Chemically Reacting Gas Mixture
Lecture 15 - Degree of Ionization of Gas Molecules
Lecture 16 - Problems on Ionization of Gas Molecules
Lecture 17 - Microcanonical and Grand Canonical Ensemble
Lecture 18 - Isobaric Isothermal Ensemble
Lecture 19 - Fluctuations in Grand canonical and Isothermal Isobaric Ensembles
Lecture 20 - Semi Grand Canonical Ensemble and Comparison of Ensembles
Lecture 21 - Problems and Adsorbtion Isotherms
Lecture 22 - Virial Equation of State for Polyatomic Molecules
Lecture 23 - Virial Equation of State
Lecture 24 - Virial Equation of State with Higher Order Terms
Lecture 25 - Thermodynamic Properties from Virial Equation of State
Lecture 26 - Interaction Potentials for Spherical Molecules
Lecture 27 - Inferences from Intermolecular Potentials
Lecture 28 - Engineering Application of Virial Equation of State
Lecture 29 - Einstein Model
Lecture 30 - Einstein Model (Continued...)
Lecture 31 - Debye Model
Lecture 32 - Sublimation Pressure and Enthalpy of Crystals
Lecture 33 - Flory Huggin's Model
Lecture 34 - Ising Model
Lecture 35 - Radial Distribution Function
Lecture 36 - Radial Distribution Function
Lecture 37 - Molecular Dynamics Simulations
Lecture 38 - Square well Potential and Barker Henderson Pertubation Theory
