Mechanical Engineering Thermodynamics
Chapter 1: Introduction
Chapter 2: Energy Transfer and Analysis
Chapter 3: Properties of Pure Substances
Chapter 4: Mass and Energy Analysis of Closed Systems
Chapter 5: Second Law of Thermodynamics
Chapter 6: Entropy
Chapter 7: Exergy
Chapter 8: Gas Power Cycles
Lesson 1: Introduction to Refrigeration Cycles
Lesson 3: Reversed Carnot Cycle
Lesson 4: Ideal vs Actual Vapor-Compression Refrigeration Cycle
Lesson 5: Heat Pumps
Lesson 6: Absorption Refrigeration Systems
Chapter 9: Vapor and Combined Power Cycles
Chapter 10: Refrigeration Cycles
Chapter 11: Thermodynamic Property Relations
Chapter 12: Gas Mixtures
Chapter 13: Gas-Vapor Mixtures and Air Conditioning
Chapter 14: Chemical Reactions and Phase Equilibrium
Chapter 15: Compressible Flow
Link to Textbook: Thermodynamics: An Engineering Approach 9th Edition
Chemical Engineering Thermodynamics
Chapter 1: Introduction
Chapter 2: The Energy Balance
Chapter 3: Entropy
Chapter 4: Thermodynamics of Processes
Chapter 5: Engineering Equations of State for PVT Properties
Chapter 6: Departure Functions
Chapter 7: Phase Equilibrium in a Pure Fluid Fluid
Chapter 8: Introduction to Multicomponent Systems
Chapter 9: Activity Models
Chapter 10: Phase Equilibria for Liquid-Liquid, Solid-Liquid, and Mixtures by an Equation of State
Chapter 11: Reaction Equilibria
Chapter 12: Electrolyte Solutions
Link to Textbook: Introductory Chemical Engineering Thermodynamics, 2nd Edition by Elliot and Lira
Heat Transfer
Chapter 1: Thermal Conductivity and the Mechanisms of Energy Transport
Chapter 2: Shell Energy Balances
Chapter 3: Equations of Change for
Nonisothermal Systems
Chapter 4: Temperature Distributions in
Turbulent Flow
Chapter 5: Dimensional Analysis in
Nonisothermal Systems
Chapter 6: Interphase Transport in
Nonisothermal Systems
Chapter 7: Macroscopic Balances for
Nonisothermal Systems
Chapter 8: Energy Transport by Radiation
Link to Textbook: Introductory Transport Phenomena by Bird, Stewart, Lightfoot and Klingenberg