Spin Relaxation in Optical Pumping
- 1 January 1962
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 36 (1), 135-140
- https://doi.org/10.1063/1.1732283
Abstract
The spin relaxation of optically aligned rubidium vapor has been studied as a function of helium buffer gas pressure. Relaxation times as long as 0.68 sec were observed in helium at ½‐atm pressure. The diffusion constant D0 for rubidium in helium at 50°C was evaluated as 0.54 cm2 sec—1. The disorientation cross section σ for rubidium‐helium collisions was found to be 6.2×10—25 cm2. A mechanism for spin relaxation in optically aligned alkali vapors is proposed and discussed. It is found that the relaxation arises from the coupling of the alkali electron spin to orbital and rotational motion accompanying the collision. The variation of σ for rubidium in the presence of other inert gases is also discussed.Keywords
This publication has 8 references indexed in Scilit:
- Phosphorescence Lifetime of Benzene. An Intermolecular Heavy-Atom Effect, a Deuterium Effect, and a Temperature EffectThe Journal of Chemical Physics, 1960
- Spin Relaxation and Line Width in Alkali Metal VaporsPhysical Review B, 1960
- Spin Relaxation of Optically Aligned Rubidium VaporPhysical Review B, 1959
- Composition Dependence of the Diffusion Coefficient of the System A—XeThe Journal of Chemical Physics, 1958
- Molecular Diffusion Studies in Gases at High Temperature. II. Interpretation of Results on the He–N2 and CO2–N2 SystemsThe Journal of Chemical Physics, 1958
- Slow Spin Relaxation of Optically Polarized Sodium AtomsPhysical Review B, 1957
- Collisional Perturbation of Spin-Orbital Coupling and the Mechanism of Fluorescence Quenching. A Visual Demonstration of the PerturbationThe Journal of Chemical Physics, 1952
- The Coupling of Angular Momentum Vectors in MoleculesReviews of Modern Physics, 1951