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2/18/2014PHY 770 Spring 2014 -- Lecture 10-111 PHY 770 -- Statistical Mechanics 11 AM – 12:15 & 12:30-1:45 PM TR Olin 107 Instructor: Natalie Holzwarth.

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Presentation on theme: "2/18/2014PHY 770 Spring 2014 -- Lecture 10-111 PHY 770 -- Statistical Mechanics 11 AM – 12:15 & 12:30-1:45 PM TR Olin 107 Instructor: Natalie Holzwarth."— Presentation transcript:

1 2/18/2014PHY 770 Spring 2014 -- Lecture 10-111 PHY 770 -- Statistical Mechanics 11 AM – 12:15 & 12:30-1:45 PM TR Olin 107 Instructor: Natalie Holzwarth (Olin 300) Course Webpage: http://www.wfu.edu/~natalie/s14phy770http://www.wfu.edu/~natalie/s14phy770 Lecture 10-11 -- Chapter 5 Equilibrium Statistical Mechanics Canonical ensemble  Probability density matrix  Canonical ensembles; comparison with microcanonical ensembles  Ideal gas  Lattice vibrations

2 2/18/2014PHY 770 Spring 2014 -- Lecture 10-112

3 2/18/2014PHY 770 Spring 2014 -- Lecture 10-113

4 2/18/2014PHY 770 Spring 2014 -- Lecture 10-114

5 2/18/2014PHY 770 Spring 2014 -- Lecture 10-115 Microscopic definition of entropy – due to Boltzmann Consider a system with N particles having a total energy E and a macroscopic parameter n. denotes the multiplicity of microscopic states having the same parameters. Each of these states are assumed to equally likely to occur. Alternative description of entropy in terms of probability density (attributed to Gibbs)

6 2/18/2014PHY 770 Spring 2014 -- Lecture 10-116 Probability density -- continued

7 2/18/2014PHY 770 Spring 2014 -- Lecture 10-117 Example of classical treatment of microstate analysis of N three dimensional particles in volume V with energy E

8 2/18/2014PHY 770 Spring 2014 -- Lecture 10-118 Example of classical treatment of microstate analysis of N three dimensional particles in volume V with energy E -- continued Rough statement of equivalence of Boltzmann’s and Gibbs’ entropy analysis for this and similar cases:

9 2/18/2014PHY 770 Spring 2014 -- Lecture 10-119 Quantum representation of density matrix

10 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1110 Microcanonical ensemble: Consider a closed, isolated system in equilibrium characterized by a time-independent Hamiltonian with energy eigenstates. This implies that the density matrix is constant in time and is diagonal in the energy eigenstates:

11 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1111 Microcanonical ensemble -- continued

12 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1112 Summary of results for microcanonical ensemble – Isolated and closed system in equilibrium with fixed energy E: Now consider a closed system which can exchange energy with surroundings – canonical ensemble Two viewpoints Optimization with additional constraints Explicit treatment of effects of surroundings

13 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1113 Canonical ensemble – derivation from optimization Find form of probability density which optimizes S with constraints

14 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1114 Canonical ensemble from optimization – continued

15 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1115 Canonical ensemble from optimization – summary of results

16 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1116 Canonical ensemble -- explicit consideration of effects of “bath” E b and “system” E s : EbEb EsEs Analogy (thanks to H. Callen, Thermodyanmics and introduction to thermostatistics) bath:system:

17 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1117 Canonical ensemble -- explicit consideration of effects of “bath” E b and “system” E s ; analogy with 3 dice bath: E b system: E s For every toss of the 3 dice, record all outcomes with a sum of 12  E tot as a function of the red dice representing E s. EsEs EbEb PsPs 15+6,6+52/25 24+6,6+4,5+53/25 33+6,6+3,4+5,5+44/25 42+6,6+2,3+5,5+3,4+45/25 51+6,6+1,2+5,5+2,3+4,4+36/25 61+5,5+1,2+4,4+2,3+35/25

18 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1118 Canonical ensemble -- explicit consideration of effects of “bath” E b and “system” E s : EbEb EsEs

19 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1119 Canonical ensemble (continued)

20 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1120 Canonical ensemble (continued)

21 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1121 Canonical ensemble (continued):

22 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1122 Canonical ensemble continued – average energy of system: Heat capacity for canonical ensemble:

23 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1123 First Law of Thermodynamics for canonical ensemble (T fixed) - Pressure associated with state s

24 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1124 =0

25 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1125

26 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1126 Canonical ensemble – summary and further results

27 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1127

28 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1128 Summary of relationship between canonical ensemble and its partition function and the Helmholz Free Energy:

29 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1129 Canonical ensemble in terms of probability density operator

30 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1130 Example: Canonical distribution for free particles

31 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1131 Example: Canonical distribution for free particles -- continued

32 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1132 Canonical ensemble of indistinguishable quantum particles Indistinguishable quantum particles generally must obey specific symmetrization rules under the exchange of two particle labels (see Appendix D of your textbook)   Bose-Einstein particles   Fermi-Dirac particles

33 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1133 Canonical ensemble of indistinguishable quantum particles Example: 3-body ideal gas confined in large volume V with momenta k 1, k 2, and k 3,

34 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1134 Canonical ensemble of indistinguishable quantum particles Example: 3-body ideal gas confined in large volume V with momenta k 1, k 2, and k 3,

35 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1135 Reduced single particle density matrix and the Maxwell-Boltzmann distribution

36 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1136 Reduced single particle density matrix and the Maxwell-Boltzmann distribution -- continued

37 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1137 Reduced single particle density matrix and the Maxwell-Boltzmann distribution -- continued T=100 T=500 T=1000 v

38 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1138 Canonical ensemble example: Einstein solid revisited Consider N independent harmonic oscillators (in general N=3 x number of lattice sites) with frequency  Consistent with result from microcanonial ensemble

39 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1139 Lattice vibrations for 3-dimensional lattice Example: diamond lattice Ref: http://phycomp.technion.ac.il/~nika/diamond_structure.html More realistic model of lattice vibrations

40 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1140

41 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1141

42 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1142

43 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1143 B. P. Pandey and B. Dayal, J. Phys. C 6, 2943 (1973)

44 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1144 B. P. Pandey and B. Dayal, J. Phys. C 6, 2943 (1973)

45 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1145 Lattice vibrations – continued Classical analysis determines the normal mode frequencies and their corresponding modes In general, for a lattice with M atoms in a unit cell, there will be 3M normal modes for each q. While the normal mode analysis for and the normal mode geometries are well approximated by the classical treatment, the quantum effects of the vibrations are important. The corresponding quantum Hamiltonian is given by:

46 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1146 Lattice vibrations continued

47 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1147 Lattice vibrations continued

48 2/18/2014PHY 770 Spring 2014 -- Lecture 10-1148 Lattice vibrations continued Debye model for g( 

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