Recorded on February 15, 2013. Slides: 00:48- 15: Fourier Transforms, NMR Intro 01:33- Fourier Series 05:49- Example: Square Wave 08:35- Fourier Transforms 11:59- Fourier Transforms, Slide 2 14:21- Fourier Transform Pairs 16:23- Fourier Transform Pairs, Slide 2 18:45- X-Ray Crystallography 21:07- X-Ray Crystallography, Slide 2 22:14- X-Ray Crystallography, Slide 3 23:07- Ion Channels 24:30- Ion Channels, Slide 2 25:12- Pulsed NMR 28:48- Free Induction Decay 30:34- Fourier Transforms 31:13- Free Induction Decay, Slide 2 32:31- 3 Peaks of the NMR signal 34:25- Stern-Gerlach Experiment 35:25- Stern-Gerlach Experiment: Classical 39:11- Stern-Gerlach Experiment: Results 39:50- Stern-Gerlach Experiment: Quantum 40:53- Electrons in a Magnetic Field 41:55- Electron Zeeman Effect 43:20- Electrons in a Magnetic Field: Gyromagnetic Ratio 45:31- Cyclotron 46:22- Electron Zeeman Effect 47:02- Nuclear Zeeman Effect

1. Symmetry and Spectroscopy I
2. Symmetry and Spectroscopy II
3. Transformation Matrices
4. Group Theory Applications
5. Rotational Spectroscopy I
6. Rotational Spectroscopy II
7. Rotational Spectroscopy III
8. Molecular Motion
9. Vibrations in Molecules
10. Anharmonic Potential.
11. First Midterm Exam Review.
12. Electronic Spectroscopy
13. Electronic Spectroscopy II
14. Electronic Spectroscopy III
15. Electronic Spectroscopy IV
16. Fourier Transforms & Introduction to Nuclear Magnetic Resonance (NMR)
17. Nuclear Magnetic Resonance II
18. Eigenstates & Eigenvalues
19. Spin Rotations T1 & T2
20. NMR Applications/ Review
21. Second Midterm Examination Review
22. The Boltzmann Distribution
23. Partition Functions I
24. Partition Functions II
25. Partition Functions
26. Final Exam Review

Principles of quantum mechanics with application to the elements of atomic structure and energy levels, diatomic molecular spectroscopy and structure determination, and chemical bonding in simple molecules. Chemistry Dept. | Physical Sciences Sch. | University of California, Irvine