Solvent effects of nitrogen chemical shifts

Solvent effects of nitrogen chemical shifts

Due to significant developments in cryogenic probe technology and the easy access to inverse detection pulse programmes (HSQC, HMBC), the sensitivity of nitrogen NMR has lately vastly improved. As a consequence, nitrogen NMR has turned into a useful and commonly available tool for solution studies o...

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Bibliographic Details
Published in:Annual reports on NMR spectroscopy Vol. 86; p. 73
Main Authors: Andersson, Hanna, Carlsson, anna-Carin, Nekoueishahraki, Bijan, Brath, Ulrika, Erdelyi, Mate
Format: Journal Article
Language:English
Published: 2015
Subjects:
14N NMR
Analytical Chemistry
Analytisk kemi
heterocycle
Läkemedelskemi
m protein
Medicinal Chemistry
metal complex
Organic Chemistry
Organisk kemi
peptide
solvent
15N NMR
chemical shift
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Summary:Due to significant developments in cryogenic probe technology and the easy access to inverse detection pulse programmes (HSQC, HMBC), the sensitivity of nitrogen NMR has lately vastly improved. As a consequence, nitrogen NMR has turned into a useful and commonly available tool for solution studies of molecular structure and properties for small organic compounds likewise biopolymers. The high sensitivity of the nitrogen lone pair to changes in the molecular environment, alterations in intra- and intermolecular interactions, and in molecular conformation along with its wide, up to 1200 ppm chemical shift dispersion make nitrogen NMR to an exceptionally sensitive reporter tool. The nitrogen chemical shift has been applied in various fields of chemistry, including for instance the studies of transition metal complexes, chemical reactions such as N-alkylation and N-oxidation, tautomerization, protonation–deprotonation equilibria, hydrogen and halogen bonding, and elucidation of molecular conformation and configuration. The 15N NMR data observed in the investigation of these molecular properties and processes is influenced by the medium it is acquired in. This influence may be due to direct coordination of solvent molecules to transition metal complexes, alteration of tautomerization equilibria, and solvent polarity induced electron density changes of conjugated systems, for example. Thus, the solvent may significantly alter the observed nitrogen NMR shifts. This review aims to provide an overview of solvent effects of practical importance, and discusses selected experimental reports from various subfields of chemistry.
ISSN:0066-4103
2163-6052
DOI:10.1016/bs.arnmr.2015.04.002