Presentation is loading. Please wait.

Presentation is loading. Please wait.

Recall the Equipartition

Published byMyron Goodwin Modified over 5 years ago

Similar presentations

Presentation on theme: "Recall the Equipartition"— Presentation transcript:

1 Classical Statistical Mechanics: 1 dimensional Simple Harmonic Oscillator

2 Recall the Equipartition
Theorem: In the Classical Cannonical Ensemble it is easy to show that The thermal average energy of a particle per independent degree of freedom is (½ )kBT.

3 The Boltzmann Distribution
Canonical Probability Function P(E): This is defined so that P(E) dE  the probability to find a particular molecule between E & E + dE Z Define: The Energy Distribution Function (Number Density) nV(E): This is defined so that nV(E) dE  the number of molecules per unit volume with energy between E & E + dE

4 Examples: Equipartition of Energy in Classical Statistical Mechanics
Free Particle Z

5 Other Examples of the Equipartion Theorem
LC Circuit Harmonic Oscillator Free Particle in 3 D Rotating Rigid Body

6 1 D Simple Harmonic Oscillator

7 Quantum Statistical Mechanics: 1 dimensional Simple Harmonic Oscillator

8 Simple Harmonic Oscillator
Quantum Mechanical Simple Harmonic Oscillator Quantum Mechanical results for a simple harmonic oscillator with classical frequency ω are: n = 0,1,2,3,.. En The Energy is quantized! E The energy levels are equally spaced!

9 Thermal Average Energy for a Quantum Simple Harmonic Oscillator
We just discussed the fact that the Quantized Energy solution to the Schrodinger Equation for single oscillator is: n = 0,1,2,3,.. Now, let the oscillator interact with a heat reservoir at absolute temperature T, & use the Canonical Ensemble to calculate the thermal average energy: <E> or <>

10 Quantized Energy of a Single Oscillator:
On interaction with a heat reservoir at T, & using the Canonical Ensemble, the probability Pn of the Oscillator being in level n is proportional to: In the Canonical Ensemble, the average energy of the harmonic oscillator of angular frequency ω at temperature T is:

11 Straightforward but tedious math manipulation!
Thermal Average Energy: Putting in the explicit form gives: The denominator is the Partition Function Z.

12 The denominator is the Partition Function Z.
Evaluate it using the Binomial expansion for x << 1:

13 The equation for ε can be rewritten:
The Final Result is:

14 The Zero Point Energy is the minimum energy of the system.
(1) This is the Thermal Average Energy for a Single Harmonic Oscillator. The first term in the above equation is called “The Zero-Point Energy”. It’s physical interpretation is that, even at T = 0 K the oscillator will vibrate & have a non-zero energy. The Zero Point Energy is the minimum energy of the system.

15 Thermal Average Oscillator Energy:
(1) The first term in (1) is the Zero Point Energy. The denominator of second term in (1) is often written: (2) (2) is interpreted as the thermal average of the quantum number n at temperature T & frequency ω. In modern terminology, (2) is called The Bose-Einstein Distribution: or The Planck Distribution.

Download ppt "Recall the Equipartition"

Similar presentations

Heat capacity at constant volume

Heat capacity at constant volume
The Heat Capacity of a Diatomic Gas

The Heat Capacity of a Diatomic Gas
Pressure and Kinetic Energy

Pressure and Kinetic Energy
Ch2. Elements of Ensemble Theory

Ch2. Elements of Ensemble Theory
Statistical Thermodynamics

Statistical Thermodynamics
Classical Statistical Mechanics in the Canonical Ensemble.

Classical Statistical Mechanics in the Canonical Ensemble.
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”
CHAPTER 14 THE CLASSICAL STATISTICAL TREATMENT OF AN IDEAL GAS.

CHAPTER 14 THE CLASSICAL STATISTICAL TREATMENT OF AN IDEAL GAS.
1 Lecture 6 Ideal gas in microcanonical ensemble. Entropy. Sackur-Tetrode formula. De Broglie wavelength. Chemical potential. Ideal gas in canonical ensemble.

1 Lecture 6 Ideal gas in microcanonical ensemble. Entropy. Sackur-Tetrode formula. De Broglie wavelength. Chemical potential. Ideal gas in canonical ensemble.
The equipartition theorem: a classical but sometimes useful result Photons* and Planck’s black body radiation law c V -> 3R Dulong-Petit limit Example.

The equipartition theorem: a classical but sometimes useful result Photons* and Planck’s black body radiation law c V -> 3R Dulong-Petit limit Example.
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
Statistical Mechanics

Statistical Mechanics
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.
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.
Microscopic definition of entropy Microscopic definition of temperature This applies to an isolated system for which all the microstates are equally probable.

Microscopic definition of entropy Microscopic definition of temperature This applies to an isolated system for which all the microstates are equally probable.
Ch 9 pages 442-444 Lecture 18 – Quantization of energy.

Ch 9 pages Lecture 18 – Quantization of energy.
Chapter 18 Bose-Einstein Gases. 18.1 Blackbody Radiation 1.The energy loss of a hot body is attributable to the emission of electromagnetic waves from.

Chapter 18 Bose-Einstein Gases Blackbody Radiation 1.The energy loss of a hot body is attributable to the emission of electromagnetic waves from.
The Helmholtz free energyplays an important role for systems where T, U and V are fixed - F is minimum in equilibrium, when U,V and T are fixed! by using:

The Helmholtz free energyplays an important role for systems where T, U and V are fixed - F is minimum in equilibrium, when U,V and T are fixed! by using:
Chapter 5: Phonons II – Thermal Properties. What is a Phonon? We’ve seen that the physics of lattice vibrations in a crystalline solid Reduces to a CLASSICAL.

Chapter 5: Phonons II – Thermal Properties. What is a Phonon? We’ve seen that the physics of lattice vibrations in a crystalline solid Reduces to a CLASSICAL.
Lecture 9 Energy Levels Translations, rotations, harmonic oscillator

Lecture 9 Energy Levels Translations, rotations, harmonic oscillator

Similar presentations

Ads by Google