Presentation is loading. Please wait.

Presentation is loading. Please wait.

Universe = system (Ur) and reservoir (Ur,Tr) constrained by U0=Ur+Us

Published byMelinda Brooks Modified over 6 years ago

Similar presentations

Presentation on theme: "Universe = system (Ur) and reservoir (Ur,Tr) constrained by U0=Ur+Us"— Presentation transcript:

1 Universe = system (Ur) and reservoir (Ur,Tr) constrained by U0=Ur+Us
Thermal exchange only Universe = system (Ur) and reservoir (Ur,Tr) constrained by U0=Ur+Us resevoir (Ur, Tr) U system Us Maximize total entropy by minimizing Helmholtz free energy

2 Thermal and mechanical exchange
Universe = system (Us, Vs) and reservoir (Ur, Vr, Tr) constrained by U0=Ur+Us and V0=Vr+Vs resevoir (Ur, Vr, Tr) U system Us, Vs V Maximize total entropy by minimizing Gibbs free energy

3 Enthalpy When considering phase transitions, it is useful to define a quantity h called ‘enthalpy’ Because h depends only on state variables, it too must be a state variable – hence its usefulness. When a material changes phase (e.g. from a solid to a liquid) at constant temperature and pressure, latent heat l must be added. This heat of transformation is related simply to the enthalpy difference between the liquid and solid

4

5 The Tds equations

6 Thermodynamic potentials and equilibrium

Download ppt "Universe = system (Ur) and reservoir (Ur,Tr) constrained by U0=Ur+Us"

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.
Thermodynamic Potentials

Thermodynamic Potentials
Lecture 15. Phases of Pure Substances (Ch.5) Up to now we have dealt almost exclusively with systems consisting of a single phase. In this lecture, we.

Lecture 15. Phases of Pure Substances (Ch.5) Up to now we have dealt almost exclusively with systems consisting of a single phase. In this lecture, we.
Phase transitions Qualitative discussion: the 1-component system water specific volume.

Phase transitions Qualitative discussion: the 1-component system water specific volume.
EQUILIBRIUM AND KINETICS. Mechanical Equilibrium of a Rectangular Block Centre Of Gravity Potential Energy = f(height of CG) Metastable state Unstable.

EQUILIBRIUM AND KINETICS. Mechanical Equilibrium of a Rectangular Block Centre Of Gravity Potential Energy = f(height of CG) Metastable state Unstable.
Temperature, Heat, and the First Law of Thermodynamics

Temperature, Heat, and the First Law of Thermodynamics
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.
Thermodynamic relations for dielectrics in an electric field Section 10.

Thermodynamic relations for dielectrics in an electric field Section 10.
The canonical ensemble System  Heat Reservoir R T=const. adiabatic wall Consider system at constant temperature and volume We have shown in thermodynamics.

The canonical ensemble System  Heat Reservoir R T=const. adiabatic wall Consider system at constant temperature and volume We have shown in thermodynamics.
Thermodynamic Potentials Why are thermodynamic potentials useful Consider U=U(T,V) Complete knowledge of equilibrium properties of a simple thermodynamic.

Thermodynamic Potentials Why are thermodynamic potentials useful Consider U=U(T,V) Complete knowledge of equilibrium properties of a simple thermodynamic.
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
Thermo & Stat Mech - Spring 2006 Class 13 1 Thermodynamics and Statistical Mechanics Open Systems and Chemical Potential.

Thermo & Stat Mech - Spring 2006 Class 13 1 Thermodynamics and Statistical Mechanics Open Systems and Chemical Potential.
H 2 O(l) --> H 2 O(s) Normal freezing point of H 2 O = 273.15K The change in enthalpy is the enthalpy of freezing - enthalpy change associated when one.

H 2 O(l) --> H 2 O(s) Normal freezing point of H 2 O = K The change in enthalpy is the enthalpy of freezing - enthalpy change associated when one.
Thermodynamic Property Relations

Thermodynamic Property Relations
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
Thermo & Stat Mech - Spring 2006 Class 9 1 Thermodynamics and Statistical Mechanics Change of Phase.

Thermo & Stat Mech - Spring 2006 Class 9 1 Thermodynamics and Statistical Mechanics Change of Phase.
Critical Point Drying Biological specimens MEMS Aerogels Spices.

Critical Point Drying Biological specimens MEMS Aerogels Spices.

Similar presentations

Ads by Google