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Recall the Equipartition

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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.


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