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Chemistry 203: Organic Spectroscopy (Fall 2011, UC Irvine). These videos are part of a 28-lecture graduate-level course titled "Organic Spectroscopy" taught at UC Irvine by Professor James Nowick.

FREE
This course includes
Hours of videos

888 years, 9 months

Units & Quizzes

32

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Certificate of Completion

The course covers infrared (IR) spectroscopy, mass spectrometry, and nuclear magnetic resonance (NMR) spectroscopy, the latter of which is the main focus. Topics covered in the NMR spectroscopy part of the course include chemical shifts, spin-spin coupling, dynamic effects in NMR spectroscopy, and 2D NMR spectroscopy (COSY, HMQC, HMBC, TOCSY, NOESY, ROESY).

Course Currilcum

  • Lecture 01 – Infrared Spectroscopy: Introduction, Theory, Instrumentation Unlimited
  • Lecture 02 – Infrared Spectroscopy: C,H,O-Containing Functional Groups Unlimited
  • Discussion 1 – Molecular Modeling with PyMOL Unlimited
  • Lecture 03 – Effect of Ring Size Conjugation Electron-Withdrawing Groups Unlimited
  • Lecture 04 – Mass Spectrometry: Theory, Instrumentation, and Techniques Unlimited
  • Lecture 05 – Isotopic Masses, Isotopic Abundances, and High-Resolution Mass Spectrometry Unlimited
  • Lecture 05A – Isotopic Masses, Isotopic Abundances, and High-Resolution Mass Spectrometry Unlimited
  • Lecture 06 – Fragmentation in EIMS: Alkanes, Alkenes, Heteroatom Compounds Unlimited
  • Lecture 06A – Fragmentation in EIMS: Alkanes, Alkenes, Heteroatom Compounds Unlimited
  • Lecture 07 – Introduction to NMR Spectroscopy: Concepts and Theory, Part 1 Unlimited
  • Lecture 08 – Introduction to NMR Spectroscopy: Concepts and Theory, Part 2 Unlimited
  • Lecture 09 – Chemical Shift. 1H NMR Chemical Shifts Unlimited
  • Lecture 10 – 13C NMR Chemical Shifts. Chemical Equivalence and Spin-Spin Coupling Unlimited
  • Lecture 11 – Magnetic Equivalence, Spin Systems, and Pople Notation Unlimited
  • Lecture 12 – Coupling Analysis in First-Order and Near-First-Order Systems Unlimited
  • Lecture 13 – Coupling Analysis in First-Order and Near-First-Order Systems (cont.) Unlimited
  • Lecture 14 – Spin-Spin Coupling in Stereochemistry and Structure Determination Unlimited
  • Lecture 15 – Coupling Involving Other Nuclei Unlimited
  • Lecture 16 – The Importance of 13C Chemical Shifts in Structure and … Unlimited
  • Lecture 17 – Introduction to 2D NMR Spectroscopy Unlimited
  • Lecture 18 – Dynamic Effects in NMR Spectroscopy Unlimited
  • Lecture 19 – The Nuclear Overhauser Effect in Stereochemistry and Structure Determination Unlimited
  • Lecture 20 – Understanding Complex Pulse Sequences Unlimited
  • Lecture 21 – Using HMBC to Help Solve Structures: “Putting the Pieces Together” Unlimited
  • Lecture 22 – Aspects of COSY, HMQC, HMBC, and Related Experiments Unlimited
  • Lecture 23 – Using TOCSY to Elucidate Spin Systems. ROESY Unlimited
  • Lecture 24 – Using Organic Spectroscopy to Solve Complex Structures Unlimited
  • Lecture 25 – INADEQUATE. Some Thoughts on Homework Set 9 Unlimited
  • Lecture 26 – Using Organic Spectroscopy to Solve Complex Structures, Part 2 Unlimited
  • Lecture 27 – Using HMQC-TOCSY or HSQC-TOCSY to Deal with Overlap Unlimited
  • Lecture 27 – Using HMQC-TOCSY or HSQC-TOCSY to Deal with Overlap Unlimited
  • Lecture 28 – Some Other Useful NMR Techniques Unlimited