Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lecture 9 Energy Levels Translations, rotations, harmonic oscillator

Published byElfrieda Craig Modified over 8 years ago

Similar presentations

Presentation on theme: "Lecture 9 Energy Levels Translations, rotations, harmonic oscillator"— Presentation transcript:

1 Lecture 9 Energy Levels Translations, rotations, harmonic oscillator
Independence of energy storage Many particle systems Independent distinguishable particles Independent indistinguishable particles

2 Energy levels from quantum mechanics
Need to calculate the partition functions to have any use of statistical mechanics For a single particle independent modes of motion will contribute to energy and thus the partition function. For independent particles the energy is the sum of the individual particles energies All this will provide a rather simple way of calculating Q for many physical systems

3 Translation Consider a single diatomic molecule is the box
M - total mass of the molecule a,b,c - dimensions of the box containing the molecule h - Planck constant

4 Rotation and vibrations
I = ml2 - moment of inertia, m mass of one atom, l atom to atom distance Vibrations - harmonic oscillator  - frequency

5 Single gas diatomic molecule particle partition function
When energy is additive the partition function is a product of partition function Therefore free energy is the sum

6 Many independent particle
Total energy is the sum of single particle energies So the partition function is the product of single particle functions For N independent, identical, distinguishable particles

7 Indistinguishable particles
States such as: a) first particle in state one and second particle in state 2 and b) second particle in state one and first particle in state 2 are the same “total” state since particle are not distinguishable This leads to over counting of the partition function That has to be corrected by

8 Bosons and Fermions 1/N! correction is not quite right. If particles 1 and 2 are in the same state there was no over counting. This is possible for bosons. But typically number of states is much larger than number of particles so this situation is very rare and does not contribute in the thermodynamic limit to the Q, such as to affect intensive properties. For fermions two particles can not be in the same state - we over counted even with N! correction. Again for classical, not quantum systems, we are fine.

9 Problem 10.6 N distinguishable particles, each having two energy levels e1=1/2kT and e2=3/2kT. Calculate energy, entropy and heat capacity at constant volume. Particles are bosons.

Download ppt "Lecture 9 Energy Levels Translations, rotations, harmonic oscillator"

Similar presentations

Lecture 11a Ideal gas Number of states and density of states Partition functions q and Q Thermodynamic Functions Problem 12.9.

Lecture 11a Ideal gas Number of states and density of states Partition functions q and Q Thermodynamic Functions Problem 12.9.
Lecture 27 Electron Gas The model, the partition function and the Fermi function Thermodynamic functions at T = 0 Thermodynamic functions at T > 0.

Lecture 27 Electron Gas The model, the partition function and the Fermi function Thermodynamic functions at T = 0 Thermodynamic functions at T > 0.
Heat capacity at constant volume

Heat capacity at constant volume
15.5 Electronic Excitation

15.5 Electronic Excitation
The Heat Capacity of a Diatomic Gas

The Heat Capacity of a Diatomic Gas
Lecture 8, p 1 Lecture 8 The Second Law of Thermodynamics; Energy Exchange  The second law of thermodynamics  Statistics of energy exchange  General.

Lecture 8, p 1 Lecture 8 The Second Law of Thermodynamics; Energy Exchange  The second law of thermodynamics  Statistics of energy exchange  General.
Statistical Thermodynamics

Statistical Thermodynamics
We’ve spent quite a bit of time learning about how the individual fundamental particles that compose the universe behave. Can we start with that “microscopic”

We’ve spent quite a bit of time learning about how the individual fundamental particles that compose the universe behave. Can we start with that “microscopic”
13.4 Fermi-Dirac Distribution

13.4 Fermi-Dirac Distribution
CHAPTER 14 THE CLASSICAL STATISTICAL TREATMENT OF AN IDEAL GAS.

CHAPTER 14 THE CLASSICAL STATISTICAL TREATMENT OF AN IDEAL GAS.
Chapter 3 Classical Statistics of Maxwell-Boltzmann

Chapter 3 Classical Statistics of Maxwell-Boltzmann
Thermo & Stat Mech - Spring 2006 Class 20 1 Thermodynamics and Statistical Mechanics Heat Capacities.

Thermo & Stat Mech - Spring 2006 Class 20 1 Thermodynamics and Statistical Mechanics Heat Capacities.
MSEG 803 Equilibria in Material Systems 10: Heat Capacity of Materials Prof. Juejun (JJ) Hu

MSEG 803 Equilibria in Material Systems 10: Heat Capacity of Materials Prof. Juejun (JJ) Hu
Statistical Mechanics

Statistical Mechanics
Thermo & Stat Mech - Spring 2006 Class 22 1 Thermodynamics and Statistical Mechanics Fermi-Dirac Statistics.

Thermo & Stat Mech - Spring 2006 Class 22 1 Thermodynamics and Statistical Mechanics Fermi-Dirac Statistics.
Thermo & Stat Mech - Spring 2006 Class 19 1 Thermodynamics and Statistical Mechanics Partition Function.

Thermo & Stat Mech - Spring 2006 Class 19 1 Thermodynamics and Statistical Mechanics Partition Function.
Thermochemistry in Gaussian. The Internal Thermal Energy The internal thermal energy can be obtaine from the partition function, q. The contributions.

Thermochemistry in Gaussian. The Internal Thermal Energy The internal thermal energy can be obtaine from the partition function, q. The contributions.
Statistical Mechanics Physics 313 Professor Lee Carkner Lecture 23.

Statistical Mechanics Physics 313 Professor Lee Carkner Lecture 23.
Intro/Review of Quantum

Intro/Review of Quantum
Chapter 16: The Heat Capacity of a Solid

Chapter 16: The Heat Capacity of a Solid

Similar presentations

Ads by Google