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Course description
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Introduction to proton NMR spectroscopy and theory, magnetic properties of some nuclei, resonance event and fundamental NMR equation, relaxation, instrumentation, apparatus and sample handling, chemical shift, induced magnetic fields, magnetic anisotropy, peak integration, spin-spin coupling and coupling constants and applications, interpretation of simple spectra, peak multiplicity and relative intensities, Pascal’s triangle, spin systems, analysis of the fist-order NMR spectra, Protons on hetero-atoms of organic molecules. AMX, ABX, and ABC systems with three coupling constants, vicinal, geminal and long-range coupling, spin-spin decoupling (double resonance), shift reagents. Introduction to 13C-NMR spectrometry, Fourier transformation, free induction decay (FID), pulse, acquisition, pulse delay, proton decoupled- and coupled 13C-NMR spectra, INDOR, NOE effect, chemical shift range, peak assignments of 13C spectra, off-resonance decoupling, selective proton decoupling, deuterium substitution, chemical shift reagents and equivalence. Applications and interpretation of spectra translated into compounds. Two dimension NMR and some special techniques: Second order effect, COSY, HETCOR, INADEQUATE, DEPT, NOE, the crossover experiments...
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