Optically driven spin-alignment precession
Abstract
The effect of optically driven spin precession discovered by Bell and Bloom [W. E. Bell and A. L. Bloom, Phys. Rev. Lett. 6, 280 (1961)] is widely used nowadays as a basis for numerous experiments in fundamental physics and for diverse applications. In this paper we consider a much less popular version of the light-induced spin precession that does not imply coherent precession of the spin-system magnetization and is excited by linearly (rather than circularly) polarized light. Pump-probe measurements performed on the D2 line of cesium vapor show that the magnitude of the signal of the optically driven spin-alignment precession, in "vacuum" cells (with no buffer gas) is close to that of classical spin-orientation precession. In the presence of buffer gas, however, the signal of spin-alignment precession appears to be strongly suppressed. The discovered effect is ascribed to spin mixing of excited states of cesium atoms in the cycle of optical pumping.
Cite
@article{arxiv.2309.11123,
title = {Optically driven spin-alignment precession},
author = {A. A. Fomin and M. Yu. Petrov and A. S. Pazgalev and G. G. Kozlov and V. S. Zapasskii},
journal= {arXiv preprint arXiv:2309.11123},
year = {2023}
}
Comments
7 pages, 4 figures