Kinetic deuterium isotope effect and hydrogen bonding

2%~ diffcrcncc in chemicnt shift between hydrogen bonded protons and deutcrons has been cxzmincd bodr tlworetitally nnd cxpcrimcntaliy. it is shown that valuable information about the hydrogen bond poteM can bc cxtmcted from this isotope effect on chcmicd rhifts.

## Abstract Small, negative deuterium isotope effects on ^1^__J__(CH) have been found for a variety of simple organic molecules. These new experimental data support theoretical calculations and suggestions based on previous imprecise experimental measurements. The deuterium isotope effects upon the

## Abstract The effects of one‐bond and two‐bond ^2^H, ^13^CO and C^18^O isotope shifts on ^51^V shielding in various carbonyl–Cp–vanadium complexes (Cp = n^5^‐cyclopentadienyl) are reported and discussed with respect to the sensitivity of ^51^V shifts to bond extensions, and the rovibrationally av

The magnitude of a-secondary deuterlum klnetlc isotope effects has been used widely as a criterion of mechanism for nucleophlllc substitution reactions at saturated carbon (1,2). Although the magnitude of the isotope effect clearly

## Abstract A series of intramolecularly hydrogen‐bonded enamines, enols and enethiols with ester carbonylic, ketonic carbonylic, thioester carbonylic, nitro and sulphoxide acceptors were investigated to obtain ^13^C chemical shifts and deuterium isotope effects. Results from 33 new compounds and s

Infrared speatra>of hydrazinium hydrogen oxalate, N2H6HC20a, and of its deuterated derivative, N2D6DC20 , have heemstudied at liquid nitrogen temperature in the 3600 to 200 cm-1 range. It appears that t % e symmetric 0.. H.. 0 hydrogen bond of the hydrogen oxslate chains becomes asymmetric