NOC:Chemical Engineering Thermodynamics (2019)


Lecture 1 - Introduction


Lecture 2 - Measurability and controllability of energy


Lecture 3 - Postulates of thermodynamics - I


Lecture 4 - Postulates of thermodynamics - II


Lecture 5 - Definition of intensive variables and driving forces for temperature and pressure flow


Lecture 6 - Driving force for the matter flow


Lecture 7 - Basic properties, phase diagram, and thermodynamic table


Lecture 8 - Work, and heat


Lecture 9 - First law of thermodynamics for closed system: Ideal gas behavior


Lecture 10 - First law of thermodynamics: Example 1


Lecture 11 - First law of thermodynamics for open system


Lecture 12 - First law of thermodynamics: Example 2


Lecture 13 - The second law of the thermodynamics: Review


Lecture 14 - Carnot cycle and thermodynamic temperature


Lecture 15 - The concept of entropy


Lecture 16 - Maximum work and entropy of ideal gas


Lecture 17 - Power cycles and examples


Lecture 18 - Mathematical properties of fundamental equations


Lecture 19 - Generalized thermodynamic potential - I


Lecture 20 - Generalized thermodynamic potential - II


Lecture 21 - Multivariable Calculus


Lecture 22 - Maxwell's relations and examples


Lecture 23 - Jacobian method and its applications


Lecture 24 - Equilibrium and stability - I


Lecture 25 - Equilibrium and stability - II


Lecture 26 - Stability criteria


Lecture 27 - Intrinsic stability of thermodynamic system


Lecture 28 - Phase transitions


Lecture 29 - Clapeyron Equation and Vapour Pressure Correlations


Lecture 30 - Equation of state


Lecture 31 - Equation of state (Continued...)


Lecture 32 - Repulsive Interaction


Lecture 33 - Fugacity


Lecture 34 - Thermodynamics of mixtures


Lecture 35 - Partial molar properties and examples


Lecture 36 - Examples of partial molar properties for real processes


Lecture 37 - Obtaining the partial molar properties from experimental data


Lecture 38 - Partial molar properties of ideal gas mixtures


Lecture 39 - Chemical potential of ideal gas mixtures


Lecture 40 - Fugacity coefficient in terms of measurable properties


Lecture 41 - Fugacity coefficient for mixtures


Lecture 42 - Fugacity coefficient for ideal mixtures


Lecture 43 - Activity coefficient for mixtures


Lecture 44 - Gibbs - Duhem relations and its impacts on the activity


Lecture 45 - Excess Gibbs free energy model - I


Lecture 46 - Two suffix Margules equation


Lecture 47 - Excess Gibbs free energy model - II


Lecture 48 - Vapor Liquid Equilibria


Lecture 49 - Vapor Liquid Equilibria (examples)


Lecture 50 - Vapor Liquid Equilibria (non-ideal mixtures - I)


Lecture 51 - Vapor Liquid Equilibria (non-ideal mixtures - II)


Lecture 52 - Azeotropes


Lecture 53 - Azeotrope (binary mixture)


Lecture 54 - Liquid-Liquid equilibria - 1


Lecture 55 - liquid-liquid equilibria (Continued...) and solid-liquid equilibria


Lecture 56 - Solid-liquid equilibria (Continued...)


Lecture 57 - Solid-liquid equilibria examples and properties


Lecture 58 - Examples of boiling point elevation


Lecture 59 - Solubility of gases in the liquid


Lecture 60 - Chemical reaction equilibria - I


Lecture 61 - Chemical reaction equilibria - II


Lecture 62 - Chemical reaction equilibria - III


Lecture 63 - Chemical reaction equilibria - IV