Noise Sources in NMR Oscillators and Relaxation Phenomena in Optically Pumped Mercury Isotopes.

Abstract

Two investigations are described: the effects of noise in NMR oscillators, and spin relaxation of optically pumped Hg nuclei. A suitable noise model was provided by white-noise forcing of an NMR oscillator based on linearized Bloch equations. Experimental confirmation at the microhertz level was obtained. Measurements of Hg vapor density in one fused silica cell indicated the existence of three Hg-wall binding states. Excited Hg atoms were required to stimulate interstate transitions. Maximum spin-relaxation times for 199 Hg measured in glass and fused silica cells were, respectively, 40 and 11 min for 199 Hg and 50 and 100 sec for 201 Hg. In some fused silica cells evidence was found for a magnetic relaxation mechanism whose strength increased rapidly with temperature and may depend on the surface structure of the cell walls. By observing beats in free precession decay of 201 Hg electric quadrupole splittings as small as 1mHz were measured. Cell-intrinsic quadrupole splittings as large as 6.5mHz for fused silica and 17mHz for glass were observed. The cell-intrinsic splitting approached zero as the cell-axis-magnetic-field angle approached 55 deg. The relaxation rate on fused silica was enhanced after excited Hg atoms had been present in the cell. (Author)

Document Details

Document Type

Technical Report

Publication Date

Aug 31, 1976

Accession Number

ADA033737

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