Absolute and relative stability of an optical frequency reference based on spectral hole burning in Eu3+:Y2SiO5

Abstract

We present and analyze four frequency measurements designed to characterize the performance of an optical frequency reference based on spectral hole burning in . The first frequency comparison, between a single unperturbed spectral hole and a hydrogen maser, demonstrates a fractional frequency drift rate of 5 × 10-18 s-1. Optical-frequency comparisons between a pattern of spectral holes, a Fabry-P\'erot cavity, and an Al+ optical atomic clock show a short-term fractional frequency stability of 1 ×10-15 τ-1/2 that averages down to 2.5+1.1-0.5 × 10-16 at τ = 540~s (with linear frequency drift removed). Finally, spectral hole patterns in two different crystals located in the same cryogenic vessel are compared, yielding a short-term stability of 7 ×10-16 τ-1/2 that averages down to 5.5+1.8-0.9 × 10-17 at τ = 204~s (with quadratic frequency drift removed).