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- Properties Liquid-Vapor States of a Pure Substance
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Classroom Contents
Minimum Work of Partitioning, Gibbs Phase Rule, and Van der Waals Model in Advanced Thermodynamics - Lecture 9
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- 1 - Introduction
- 2 - Results So Far Hold for Large and Small Systems
- 3 - Review: Microscopic and Mesoscopic vs Macroscopic
- 4 - Review: Rarefaction Effects Near Walls
- 5 - Review: Neglecting Effects of Partitions
- 6 - Review: Simple-System Model Limiting Assumptions
- 7 - Review: Simple-System Model Implies Euler Relation
- 8 - Review: Main Consequence of Euler Relation
- 9 - Small Systems: Specific Properties Dependences
- 10 - Small Systems: Minimum Work of Partitioning
- 11 - Basic Simple-System Models for Pure Substances
- 12 - Extensive Properties Definition
- 13 - Specific Properties Definition
- 14 - Intensive Properties and Intensive State
- 15 - Homogeneous vs Heterogeneous States; Phases
- 16 - Gibbs Phase Rule Proof
- 17 - Gibbs Phase Rule for a Pure Substance
- 18 - Fundamental Relation for a Pure Substance
- 19 - Ideal Incompressible Solid or Fluid Model
- 20 - Ideal Gas Model
- 21 - Two-Phase States of a Pure Substance
- 22 - Properties Liquid-Vapor States of a Pure Substance
- 23 - Graphical Representation of Fundamental Relation
- 24 - The u-s-v Fundamental Surface Water
- 25 - The Mollier h-s Diagram Water
- 26 - The $p$-$v$ Diagram Water
- 27 - The $p$-$v$ Diagram Van der Waals Model
- 28 - Exergies and Efficiencies in Energy Conversion
- 29 - Exergy and Second-Law Efficiency in Cogeneration
- 30 - Exergy of Bulk Flow Interactions
