Spin-rotation relaxation in rotor solid KCN

Recent solid-state NMR studies have shown that the nuclear spin-lattice relaxation time of CsO is dominated by the chemical shift anisotropy relaxation mechanism. Those studies were performed at high magnetic field strengths and at temperatures not exceeding 320 K. We find that the spin-rotation rel

SelectIre NhlR TI mrasurements on dcutermm m pouders rotatrng at high speed at the magtc angle mdtcate that dlpolat spm dlffusmn ~~hich can bc quenched by the ortentattonal dependence of the quadrupole spbttmg, IS partially restored by the simple rotatton

Proton 7-1~ relation times in two sampks of methaemogIobiin with different 'sifter wntents showed t&t a process occurs vrith a correhtion time of the order le sat 240 K-This is probably an exchange of moIecufes between bound and free vater. In a previous paper [I] we reported the temperature depend

Proton spin-&t&u refasation times rvere measured in soIid NI-I.+CIOq from 80 to 400°K. Relow 200°K the observed relsstltion times are due to dipoh interaction, abox that iemp--rature spin-rotational interactions become predominani. A potential barrier of 0.70 kcal mole-' was obtained for the reorie