Modern Physics: Statistical Mechanics 2013 (Leonard Susskind / Stanford U)

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source:  Stanford      Last updated on 2013年5月26日

Statistical Mechanics Lecture 1 1:47:39
Statistical Mechanics Lecture 2 54:13
Statistical Mechanics Lecture 3 1:53:27
Statistical Mechanics Lecture 4 1:42:35
Statistical Mechanics Lecture 5 1:35:45
Statistical Mechanics Lecture 6 2:03:30
Statistical Mechanics Lecture 7 1:50:27

Modern Physics: Statistical Mechanics 2009 (Leonard Susskind / Stanford U)

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source: Stanford      Last updated on 2014年9月25日
This Stanford Continuing Studies course is the sixth of a six-quarter sequence of classes exploring the essential theoretical foundations of modern physics. The topics covered in this course focus on quantum mechanics. The course is taught by Leonard Susskind, the Felix Bloch Professor of Physics at Stanford University.

Lecture 1 | Modern Physics: Statistical Mechanics 2:00:52
Lecture 2 | Modern Physics: Statistical Mechanics 46:49
Lecture 3 | Modern Physics: Statistical Mechanics 1:55:50
Lecture 4 | Modern Physics: Statistical Mechanics 1:35:47
Lecture 5 | Modern Physics: Statistical Mechanics 1:47:44
Lecture 6 | Modern Physics: Statistical Mechanics 1:12:58
Lecture 7 | Modern Physics: Statistical Mechanics 1:39:55
Lecture 8 | Modern Physics: Statistical Mechanics 1:37:32
Lecture 9 | Modern Physics: Statistical Mechanics 1:32:32
Lecture 10 | Modern Physics: Statistical Mechanics 1:43:39

Statistical Mechanics II: Statistical Physics of Fields (Spring 2014) by Mehran Karda at MIT

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source: MIT OpenCourseWare     Last updated on 2015年5月14日
MIT 8.334 Statistical Mechanics II: Statistical Physics of Fields, Spring 2014
View the complete course: http://ocw.mit.edu/8-334S14
Instructor: Mehran Kardar
This is the second term in a two-semester course on statistical mechanics. Basic principles are examined in this class, such as the laws of thermodynamics and the concepts of temperature, work, heat, and entropy. Topics from modern statistical mechanics are also explored, including the hydrodynamic limit and classical field theories.
License: Creative Commons BY-NC-SA
More information at http://ocw.mit.edu/terms
More courses at http://ocw.mit.edu

1. Collective Behavior, from Particles to Fields Part 1 1:16:04
2. Lec 1 (continued); The Landau-Ginzburg Approach Part 1 1:24:13
3. The Landau-Ginzburg Approach Part 2 1:25:11
4. The Landau-Ginzburg Approach Part 3 1:18:43
5. The Landau-Ginzburg Approach Part 4 1:18:47
6. The Scaling Hypothesis Part 1 1:21:33
7. The Scaling Hypothesis Part 2 1:16:41
8. The Scaling Hypothesis Part 3 1:21:29
9. Perturbative Renormalization Group Part 1 1:21:38
10. Perturbative Renormalization Group Part 2 1:22:46
11. Perturbative Renormalization Group Part 3 1:28:00
12. Perturbative Renormalization Group Part 4 1:23:10
13. Position Space Renormalization Group, Part 1 1:22:58
14. Position Space Renormalization Group, Part 2 1:19:44
15. Series Expansions Part 1 1:18:15
16. Series Expansions Part 2 1:21:49
17. Series Expansions Part 3 50:26
18. Series Expansions Part 4 1:19:53
19. Series Expansions Part 5 1:19:53
20. Continuous Spins at Low Temperatures Part 1 1:22:47
21. Continuous Spins at Low Temperatures Part 2 1:21:19
22. Continuous Spins at Low Temperatures Part 3 1:22:01
23. Continuous Spins at Low Temperatures Part 4 1:20:41
24. Dissipative Dynamics 1:25:17
25. Continuous Spins at Low Temperatures Part 5 1:21:16
26. Continuous Spins at Low Temperatures Part 6 1:23:56

Statistical Mechanics I: Statistical Mechanics of Particles (Fall 2013) by Mehran Kardar at MIT

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source: MIT OpenCourseWare     Last updated on 2014年12月21日
View the complete course: http://ocw.mit.edu/8-333F13
Instructor: Mehran Kardar
Statistical Mechanics is a probabilistic approach to equilibrium properties of large numbers of degrees of freedom. In this two-semester course, basic principles are examined. Topics include: Thermodynamics, probability theory, kinetic theory, classical statistical mechanics, interacting systems, quantum statistical mechanics, and identical particles.
License: Creative Commons BY-NC-SA
More information at http://ocw.mit.edu/terms
More courses at http://ocw.mit.edu

1. Thermodynamics Part 1 1:26:25
2. Thermodynamics Part 2 1:23:38
3. Thermodynamics Part 3 1:23:44
4. Thermodynamics Part 4 1:18:53
5. Probability Part 1 1:21:30
6. Probability Part 2 1:24:53
7. Kinetic Theory of Gases Part 1 1:18:39
8. Kinetic Theory of Gases Part 2 1:15:56
9. Kinetic Theory of Gases Part 3 1:25:36
10. Kinetic Theory of Gases Part 4 1:25:18
11. Kinetic Theory of Gases Part 5 1:22:23
12. Classical Statistical Mechanics Part 1 1:25:39
13. Classical Statistical Mechanics Part 2 1:22:35
14. Classical Statistical Mechanics Part 3 1:25:17
15. Interacting Particles Part 1 1:25:42
16. Interacting Particles Part 2 1:22:06
17. Interacting Particles Part 3 1:23:18
18. Interacting Particles Part 4 1:24:22
19. Quantum Statistical Mechanics Part 1 1:19:18
20. Quantum Statistical Mechanics Part 2  1:23:32
21. Ideal Quantum Gases Part 1 1:23:48
22. Ideal Quantum Gases Part 2 1:20:31
23. Ideal Quantum Gases Part 3 1:23:42
24. Ideal Quantum Gases Part 4 1:23:42
25. Ideal Quantum Gases Part 5 1:22:55
26. Ideal Quantum Gases Part 6 1:21:05