Design of an optical reference cavity with low thermal noise and flexible thermal expansion properties

TL;DR

This paper presents a novel optical reference cavity design with low thermal noise and tunable thermal expansion properties, enabling stable operation near room temperature for various cavity lengths.

Contribution

The paper introduces a cavity design with re-entrant fused silica mirrors and a ULE spacer that achieves low thermal noise and adjustable zero crossing temperature of CTE.

Findings

Thermal noise limit of $1\times10^{-16}$ achieved.

CTE zero crossing temperature can be tuned from -10°C to 23°C.

Vibration immunity is improved through structure optimization.

Abstract

An ultrastable optical reference cavity with re-entrant fused silica mirrors and a ULE spacer structure is designed through finite element analysis. The designed cavity has a low thermal noise limit of $1\times10^{-16}$ and a flexible zero crossing temperature of the effective coefficient of thermal expansion (CTE). The CTE zero crossing temperature difference between a composite cavity and a pure ULE cavity can be tuned from $-10\ ^{\circ}$C to $23\ ^{\circ}$C, which enables operation of the designed reference cavity near room temperature without worrying about the CTE zero crossing temperature of the ULE spacer. The design can be applied to cavities with different lengths. Vibration immunity of the cavity is also achieved through structure optimization.