Presentation is loading. Please wait.

Presentation is loading. Please wait.

General Phase Equilibrium

Published byStella Rosaline Shields Modified over 8 years ago

Similar presentations

Presentation on theme: "General Phase Equilibrium"— Presentation transcript:

1 General Phase Equilibrium
Lecture 4 General Phase Equilibrium Minimum Energy Principle Degrees of freedom Gibbs-Duhem equation Equilibrium in multiphase systems Gibbs phase rule Problems

2 Minimum Energy Principle
Maximum entropy principle: For isolated system the entropy is maximum in equilibrium Minimum energy principle: For a system kept at constant entropy and volume the energy is minimum in equilibrium The two principles are equivalent

3 Materials Stability Minimum Energy
Taylor expansion of U (S,V) around equilibrium a c b

4 Materials Stability -2 Equivalent to Equivalent to Equivalent to
We have,

5 Materials Stability - 3

6 Materials Stability - 4 Thus, Thermal stability Mechanical stability

7 State function and equilibrium
NVE dS0 NVT dF0 NPT dG0 VT d(pV) 0

8 Degrees of freedom Definition: Number of independently variable intensive properties of the system Example: For a single phase system number of intensive variables describing the system C+2, where C is number of components. For example with N components there is n chemical potentials + pressure + temperature. However, there is one relationship, so-called Gibbs-Duhem equation that relates C=2 components with each other making only C+1 independent components. For example a single component gas has only 1+1 degrees of freedom (e.g., p,V)

9 Gibb-Duhem equation From definition of G But we also know that Thus

10 Multiphase multicomponent system
The total energy of the system is the sum of the energy of each phase i labels components, j labels phases

11 Equilibrium in multiphase multicomponent system
0th law of thermodynamics - each phase has the same T dF = 0 at const T and leads to hydrostatic equilibrium dG = 0 at const P and T gives distributive equilibrium - chemical potential of a given component is the same in every phase

12 Chemical equilibrium In equilibrium at const P and T
Example: 2H2(gas)+O2(gas) 2H2O(liquid) With dT=dP=0 In general for reaction AA+ BB CC+ DD

13 Gibbs Phase Rule At each phase the Gibbs-Duhem equation holds
Therefore # of degrees of freedom, DOF = C+2-P, where P is number of phases

14 Problem 5.2 (modified) CO (gas) + H2O (gas) H2(gas) + CO2 (gas)
1. Why in general equilibrium composition depends on pressure 2. Is this the case for the reactions: and CO (gas) + H2O (gas) H2(gas) + CO2 (gas) 2H2(gas)+O2(gas) 2H2O(liquid)

Download ppt "General Phase Equilibrium"

Similar presentations

Lecture 24 Chemical equilibrium Equilibrium constant Dissociation of diatomic molecule Heterophase reactions.

Lecture 24 Chemical equilibrium Equilibrium constant Dissociation of diatomic molecule Heterophase reactions.
The thermodynamics of phase transformations

The thermodynamics of phase transformations
Thermodynamic Potentials

Thermodynamic Potentials
Thermodynamics, Systems, Equilibrium & Energy

Thermodynamics, Systems, Equilibrium & Energy
CHEMICAL AND PHASE EQUILIBRIUM (1)

CHEMICAL AND PHASE EQUILIBRIUM (1)
Solutions Lecture 6. Clapeyron Equation Consider two phases - graphite & diamond–of one component, C. Under what conditions does one change into the other?

Solutions Lecture 6. Clapeyron Equation Consider two phases - graphite & diamond–of one component, C. Under what conditions does one change into the other?
8.5 The Helmholtz Function The change in internal energy is the heat flow in an isochoric reversible process. The change in enthalpy H is the heat flow.

8.5 The Helmholtz Function The change in internal energy is the heat flow in an isochoric reversible process. The change in enthalpy H is the heat flow.
Equilibrium and Stability

Equilibrium and Stability
MSEG 803 Equilibria in Material Systems 8: Statistical Ensembles Prof. Juejun (JJ) Hu

MSEG 803 Equilibria in Material Systems 8: Statistical Ensembles Prof. Juejun (JJ) Hu
MSEG 803 Equilibria in Material Systems 4: Formal Structure of TD Prof. Juejun (JJ) Hu

MSEG 803 Equilibria in Material Systems 4: Formal Structure of TD Prof. Juejun (JJ) Hu
The Advanced Chemical Engineering Thermodynamics The retrospect of the science and the thermodynamics Q&A -1- 9/16/2005(1) Ji-Sheng Chang.

The Advanced Chemical Engineering Thermodynamics The retrospect of the science and the thermodynamics Q&A -1- 9/16/2005(1) Ji-Sheng Chang.
Lecture 6 (9/27/2006) Crystal Chemistry Part 5: Mineral Reactions Phase Equilibrium/Stability Intro to Physical Chemistry.

Lecture 6 (9/27/2006) Crystal Chemistry Part 5: Mineral Reactions Phase Equilibrium/Stability Intro to Physical Chemistry.
Observables. Molar System The ratio of two extensive variables is independent of the system size.  Denominator N as particle  Denominator N as mole.

Observables. Molar System The ratio of two extensive variables is independent of the system size.  Denominator N as particle  Denominator N as mole.
The Advanced Chemical Engineering Thermodynamics The variables (thermodynamic properties) and the equations in thermodynamics Q&A -2- 9/22/2005(2) Ji-Sheng.

The Advanced Chemical Engineering Thermodynamics The variables (thermodynamic properties) and the equations in thermodynamics Q&A -2- 9/22/2005(2) Ji-Sheng.
1 Ch3. The Canonical Ensemble Microcanonical ensemble: describes isolated systems of known energy. The system does not exchange energy with any external.

1 Ch3. The Canonical Ensemble Microcanonical ensemble: describes isolated systems of known energy. The system does not exchange energy with any external.
Thermodynamics and Statistical Mechanics

Thermodynamics and Statistical Mechanics
Pure Component VLE in Terms of Fugacity

Pure Component VLE in Terms of Fugacity
Predicting Equilibrium and Phases, Components, Species Lecture 5.

Predicting Equilibrium and Phases, Components, Species Lecture 5.
1/21/2014PHY 770 Spring 2014 -- Lecture 3 & 41 PHY 770 -- Statistical Mechanics 12:30-1:45 PM TR Olin 107 Instructor: Natalie Holzwarth (Olin 300) Course.

1/21/2014PHY 770 Spring Lecture 3 & 41 PHY Statistical Mechanics 12:30-1:45 PM TR Olin 107 Instructor: Natalie Holzwarth (Olin 300) Course.
ESS 材料熱力學 3 Units (Thermodynamics of Materials)

ESS 材料熱力學 3 Units (Thermodynamics of Materials)

Similar presentations

Ads by Google