NPTEL : NOC:Chemical Principles-II (Chemistry and Biochemistry)

Co-ordinators : Prof. Arnab Mukherjee


Lecture 1 - Introduction to The Thermodynamics

Lecture 2 - History of Thermodynamic

Lecture 3 - Thermodynamic Systems and Variables

Lecture 4 - Zeroth Law of Thermodynamic

Lecture 5 - Microscopic Definition of Temperature - Part 1

Lecture 6 - Microscopic Definition of Temperature - Part 2

Lecture 7 - Different Forms of Energy

Lecture 8 - Real Gas and Virial Equation

Lecture 9 - Van der Waals Gas

Lecture 10 - Work and Heat - Part 1

Lecture 11 - Work and Heat - Part 2

Lecture 12 - First Law of Thermodynamics

Lecture 13 - Microscopic Definition of Heat and Work

Lecture 14 - Work done at a Constant Temperature

Lecture 15 - Heat is a path function

Lecture 16 - Joule-Thomson Effect (For Ideal Gases)

Lecture 17 - Joule-Thomson Effect (For Van der Waals gas)

Lecture 18 - Adiabatic Reversible Work

Lecture 19 - Adiabatic Irreversible Work

Lecture 20 - Tutorial Problem - 1

Lecture 21 - Tutorial Problem - 2

Lecture 22 - Thermochemistry - Part 1

Lecture 23 - Thermochemistry - Part 2

Lecture 24 - Second Law of Thermodynamics

Lecture 25 - Statements of the Second Law of Thermodynamics

Lecture 26 - Carnot Cycle and Definition of Entropy

Lecture 27 - Ideal Stirling Engine

Lecture 28 - Gasoline Engine and Diesel Engine

Lecture 29 - Carnot’ Cycle: The Most Efficient Engine

Lecture 30 - Thermodynamic Temperature

Lecture 31 - Definition of Entropy

Lecture 32 - Tutorial Problem - 3

Lecture 33 - Tutorial Problem - 4

Lecture 34 - Tutorial Problem - 5

Lecture 35 - Tutorial Problem - 6

Lecture 36 - Tutorial Problem - 7

Lecture 37 - Tutorial Problem - 8

Lecture 38 - Statistical Formulation of the Second Law

Lecture 39 - Probability

Lecture 40 - Microstates and Distributions

Lecture 41 - Permutation and Combination

Lecture 42 - Two-Level Systems

Lecture 43 - Most Probable Distribution

Lecture 44 - Calculation with Multi-Level systems

Lecture 45 - Calculation with Multi-Level systems with fixed energy - Part 1

Lecture 46 - Calculation with Multi-Level systems with fixed energy - Part 2

Lecture 47 - Calculation with Multi-Level systems with fixed energy - Part 3

Lecture 48 - Bose-Einstein, Fermi-Dirac and Maxwell-Boltzmann distribution

Lecture 49 - Most Probable Distribution is the Boltzmann Distribution

Lecture 50 - Demonstration of Boltzmann Distribution

Lecture 51 - Estimating Entropy for Various Processes

Lecture 52 - Microscopic equivalent of Heat and Work

Lecture 53 - Probability and Boltzmann Distribution

Lecture 54 - Thermodynamic Observables: It is all in the Average

Lecture 55 - Tutorial Problem - 9

Lecture 56 - Tutorial Problem - 10

Lecture 57 - Tutorial Problem - 11

Lecture 58 - Tutorial Problem - 12

Lecture 59 - Thermodynamic free energy

Lecture 60 - Condition for Spontaneity

Lecture 61 - Legendre Transformation of Thermodynamic Potentials

Lecture 62 - Maxwell Relations and Applications

Lecture 63 - Thermodynamic Relations using Jacobian Method - Part 1

Lecture 64 - Thermodynamic Relations using Jacobian Method - Part 2

Lecture 65 - Tutorial Problem - 13

Lecture 66 - Tutorial Problem - 14

Lecture 67 - Tutorial Problem - 15

Lecture 68 - Tutorial Problem - 16

Lecture 69 - Chemical Principle II - Overview and Road Ahead