13: Nuclear Magnetic Resonance Spectroscopy
- Page ID
- 183015
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Learning Objectives
After reading this chapter and completing ALL the exercises, a student can be able to
- explain how 1H NMR spectrometers work - refer to section 12.1
- interpret chemical shifts of 1H NMR spectra as they relate to shielding and deshielding - refer to section 12.2 and 12.14
- explain the delta scale of 1H NMR spectra - refer to section 12.3
- recognize equivalent protons within an organic compound - refer to section 12.4
- correlate functional group structural features with chemical shifts - refer to section 12.5
- determine the proton ratio from 1H NMR spectra peak integration data - refer to section 12.6
- explain and interpret spin-spin splitting patterns in 1H NMR spectra - refer to section 12.7
- explain and interpret spin-spin splitting patterns in 1H NMR spectra - refer to section 12.8
- describes examples of some uses of 1H NMR spectroscopy - refer to section 12.9
- explain how 13C NMR spectrometers work - refer to section 12.10
- interpret the chemical shifts of 13C NMR spectra to determine the structural features of organic compounds - refer to section 12.11 and 12.14
- explain how DEPT (distortionless enhancement by polarization transfer) is used to determine the number of hydrogens bonded to each carbon - refer to section 12.12
- describes some uses of 13C NMR spectroscopy - refer to section 12.13