Temperature-dependent mechanical losses of Eu3+:Y2SiO5 for spectral hole burning laser stabilization

Abstract

We investigate the mechanical loss characteristics of Eu3+:Y2SiO5x2013a promising candidate for ultra-low-noise frequency stabilization through the spectral hole burning technique. Three different mechanical oscillators with varying surface-to-volume ratios and crystal orientations are evaluated. In this context, we perform mechanical ringdown and spectral measurements spanning temperatures from room temperature down to 15\,K. By doing so, we measure a maximum mechanical quality factor of Q=3676, corresponding to a loss angle of φ=2.72× 10-4. For a spectral hole burning laser stabilization experiment at 300\,mK, we can estimate the Allan deviation of the fractional frequency instability due to Brownian thermal noise to be below σδ /0 = 2.5× 10-18, a value lower than the estimated thermal-noise limit of any current cavity-referenced ultra-stable laser experiment.