Carbon-13 and platinum-195 spin-lattice relaxation times of tetrabutylammonium pyridinetrichloroplatinate(II)

## Measurements of the enhancement, by various electrolytes, of the spin-lattice relaxation time of carbon-13 at different locations in a number of amino acids are reported. Spin-lattice relaxation times T 1 of all the carbons in amino acids generally tend to decrease with increase in the concentr

## Abstract Carbon‐13 spin‐lattice relaxation times (__T__~1~) and ^13^C‐{^19^F} nuclear Overhauser enhancement (NOE) factors have been measured for some simple fluorocarbons by pulse‐Fourier transform methods—‘progressive saturation’ and ‘dynamic Overhauser enhancement’. The NOE factors are shown

Relaxation calculations for rapidly spinning samples show that spin-lattice relaxation time (T 1Z ) anisotropy varies with the angle between the rotor spinning axis and the external field. When the rate of molecular motion is in the extreme narrowing limit, the measurement of T 1Z anisotropies for t

Nuclear magnetic resonance of 13C is used to probe the overall and internal motions of proline. Spin-lattice relaxation times (TI) are reported for proline monomer dissolved in water/glycerol mixtures. Rates of overall molecular motion and internal motion depend on solvent composition but to differe

## Abstract ^13^C spin–lattice relaxation times (__T__~1~'s) are reported for C‐3 of 2‐methylindole (methyl,3‐^13^C~2~) as a function of the concentration of added 1,3,5‐trinitrobenzene at 35°C in 1,2‐dichloroethane. The observed decreases in __T__~1~, with increasing concentrations of 1,3,5‐trinit