Thermodynamics and Chemical Dynamics (Spring 2012)--Reginald Penner / UC Irvine

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source: UCIrvineOCW       上次更新日期:2015年1月26日
UCI Chem 131C Thermodynamics and Chemical Dynamics (Spring 2012)
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Description: In Chemistry 131C, students will study how to calculate macroscopic chemical properties of systems. This course will build on the microscopic understanding (Chemical Physics) to reinforce and expand your understanding of the basic thermo-chemistry concepts from General Chemistry (Physical Chemistry.) We then go on to study how chemical reaction rates are measured and calculated from molecular properties. Topics covered include: Energy, entropy, and the thermodynamic potentials; Chemical equilibrium; and Chemical kinetics.
Thermodynamics and Chemical Dynamics (Chem 131C) is part of OpenChem:http://ocw.uci.edu/openchem/

UC Irvine OpenCourseWare 0:22
Lecture 01. Syllabus, Homework, & Lectures. 50:03
Lecture 02. The Boltzmann Distribution Law. 53:42
Lecture 03. Energy and q (The Partition Function). 25:32
Lecture 04. Entropy. 44:40
Lecture 05. The Equipartition Theorum. 51:06
Lecture 06. The Rotational Partition Function. 32:53
Lecture 07. Vibrational Partition Functions. 49:07
Lecture 08. The First Law. 48:26
Lec 9. The First Law (review) & Adiabatic Processes Part II 26:09
Lecture 10. Jim Joule. 47:57
Lecture 11. Midterm I Review. 22:45
Lecture 12. Entropy and The Second Law. 38:05
Lecture 13. The Carnot Cycle. 46:12
Lecture 14. The Gibbs Energy. 29:49
Lecture 15. Getting to Know The Gibbs Energy. 43:43
Lecture 16. The Chemical Potential. 51:54
Lecture 17. Finding Equilibrium 32:40
Lecture 18. Equilibrium In Action. 48:13
Lecture 19. Observational Chemical Kinetics 48:29
Lecture 20. The Integrated Rate Law. 34:05
Lecture 21. The Steady State Approximation. 49:29
Lecture 22. Midterm Exam Review. 49:35
Lecture 23: Lindemann-Hinshelwood Part I 50:53
Lecture 24. Lindemann-Hinshelwood Part II 31:07
Lecture 25. Enzymes Pt. II 47:52
Lecture 26. Transition State Theory 52:21
Lecture 27. The Final Exam 51:15