Media Storage Type : 32 GB USB Stick
NPTEL Subject Matter Expert : Prof. Biman Bagchi
NPTEL Co-ordinating Institute : IIT Bombay
NPTEL Lecture Count : 61
NPTEL Course Size : 14 GB
NPTEL PDF Text Transcription : Available and Included
NPTEL Subtitle Transcription : Available and Included (SRT)
Lecture Titles:
Lecture 1 - Why Study Statistical Mechanics?
Lecture 2 - Thermodynamics
Lecture 3 - Probability Theory - Part 1
Lecture 4 - Probability Theory - Part 2
Lecture 5 - Fundamental concepts and Postulates of Statistical Mechanics - Part 1
Lecture 6 - Fundamental concepts and Postulates of Statistical Mechanics - Part 2
Lecture 7 - From Postulates to Formulation
Lecture 8 - Microcanonical Ensemble
Lecture 9 - Relation with Thermodynamics in Microcanonical Ensemble - Part 1
Lecture 10 - Relation with Thermodynamics in Microcanonical Ensemble - Part 2
Lecture 11 - Canonical Ensemble - Part 1
Lecture 12 - Canonical Ensemble - Part 2
Lecture 13 - Thermodynamic Potential for Canonical ensemble
Lecture 14 - Grand Canonical Ensemble
Lecture 15 - Thermodynamic Potentials for Grand Canonical and Isothermal-Isobaric ensembles
Lecture 16 - Fluctuations and Response Function - Part 1
Lecture 17 - Fluctuations and Response Function - Part 2
Lecture 18 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 1
Lecture 19 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 2
Lecture 20 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 3
Lecture 21 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 4
Lecture 22 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 5
Lecture 23 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 1
Lecture 24 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 2
Lecture 25 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 3
Lecture 26 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 4
Lecture 27 - Ideal Gas of Polyatomic molecules
Lecture 28 - Cluster Expansion and Mayer’s Theory of Condensation - Part 1
Lecture 29 - Cluster Expansion and Mayer’s Theory of Condensation - Part 2
Lecture 30 - Cluster Expansion and Mayer’s Theory of Condensation - Part 3
Lecture 31 - Cluster Expansion and Mayer’s Theory of Condensation - Part 4
Lecture 32 - Cluster Expansion and Mayer’s Theory of Condensation - Part 5
Lecture 33 - Cluster Expansion and Mayer’s Theory of Condensation - Part 6
Lecture 34 - Phase Transition and Landau Theory - Part 1
Lecture 35 - Phase Transition and Landau Theory - Part 2
Lecture 36 - Phase Transition and Landau Theory - Part 3
Lecture 37 - Comments on some important Concepts of Statistical Mechanics
Lecture 38 - Nucleation Part 1: Introduction, Thermodynamics of Nucleation
Lecture 39 - Nucleation Part 2: Kinetics of Nucleation
Lecture 40 - Nucleation Part 3: Kinetics of Nucleation, Classical Nucleation Theory, Heterogeneous Nucleation
Lecture 41 - Nucleation Part 4: Ostwald Step Rule
Lecture 42 - Spinodal Decomposition and Pattern Formation: Evolution of Structure through Dynamics - Part 1
Lecture 43 - Spinodal Decomposition and Pattern Formation: Evolution of Structure through Dynamics - Part 2
Lecture 44 - Ising Model and Other Lattice Models - Part 1
Lecture 45 - Ising Model and Other Lattice Models - Part 2
Lecture 46 - Ising Model and Other Lattice Models - Part 3
Lecture 47 - Ising Model and Other Lattice Models - Part 4
Lecture 48 - Ising Model and Other Lattice Models - Part 5
Lecture 49 - Binary Mixtures: Towards Understanding Non-Ideality and Osmotic Pressure - Part 1
Lecture 50 - Binary Mixtures: Towards Understanding Non-Ideality and Osmotic Pressure - Part 2
Lecture 51 - Theory of Liquids - Part 1
Lecture 52 - Theory of Liquids - Part 2
Lecture 53 - Theory of Liquids - Part 3
Lecture 54 - Theory of Liquids - Part 4
Lecture 55 - Polymers in Solution and Polymer Collapse - Part 1
Lecture 56 - Polymers in Solution and Polymer Collapse - Part 2
Lecture 57 - Polymers in Solution and Polymer Collapse - Part 3
Lecture 58 - Polymers in Solution and Polymer Collapse - Part 4
Lecture 59 - Computer Simulation Methods in Statistical Mechanics - Part 1
Lecture 60 - Computer Simulation Methods in Statistical Mechanics - Part 2
Lecture 61 - Conclusion