Singel particle energy from Bolztman

1. Boltzmann number of 1-particle state >>number of particles Singel particle energy from Bolztman How many 1-particle states? Remember the sphere used to explain degeneracy? number of 1-particle states with an energy lower than e =number of lattice points enclosed by the sphere in the positive octant:

2. Many particles Boltzman energy The average energy of N particles is N times the average energy of one particle

3. yi1 yi2 yi3 yi2 yi2 yi3 yi4 yi5 yi6 NON Bolztmann ensembles Fermions: 2 particles cannot occupy the same quantum stateoccupation number nk can only be 0 or 1 P1,2y=-y antisymmetric Bosons: 2 particles can occupy the same quantum stateoccupation number nk can have any value P1,2y=+y symmetric

4. There are many ways of counting distributions, Partition functions for F or B choose Grand-Canonical Ensemble

5. Summing with occupation numbers

6. Fermions Fermi-Dirac

7. Bosons from our outstanding math background … we recognize the series Bose-Einstein Combining Bose-Einstein with the Fermi-Dirac we obtain a gral. Eq.

8. Grand-Canonical equation

9. G-canonical equations II Keep in mind that even though we started with non-interacting particles, there wavefunctions are symmetrized they are NOT INDEPENDENT

10. High T low r limit for n Boltzmann number of 1-particle state >>number of particles 

11. High T low r limit for E

12. Examples: Photon gas, an electromagnetic field in thermal equilibrium with its container Example To describe the state of the field, we need to know how many n are in each oscillator Photons are bosons  n=0,1,2,3…..

13. Cont.

14. cont The average number of photons in a state j… Planck distribution