Ultra-stable cryogenic sapphire cavity laser with an instability reaching 2 × 10⁻¹⁶ based on a low vibration level cryostat

Leilei He, Jingxuan Zhang, Zhiyuan Wang, Jialu Chang, Qiyue Wu, Zehuang Lu, and Jie Zhang

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Leilei He, Jingxuan Zhang, Zhiyuan Wang, Jialu Chang, Qiyue Wu, Zehuang Lu, and Jie Zhang, "Ultra-stable cryogenic sapphire cavity laser with an instability reaching 2 × 10⁻¹⁶ based on a low vibration level cryostat," Opt. Lett. 48, 2519-2522 (2023)

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Abstract

Cryogenic ultra-stable lasers have extremely low thermal noise limits and frequency drifts, but they are more seriously affected by vibration noise from cryostats. Main material candidates for cryogenic ultra-stable cavities include silicon and sapphire. Although sapphire has many excellent properties at low temperature, the development of sapphire-based cavities is less advanced than that of silicon-based. Using a homemade cryogenic sapphire cavity, we develop an ultra-stable laser source with a frequency instability of 2(1) × 10⁻¹⁶. This is the best frequency instability level among similar systems using cryogenic sapphire cavities reported so far. Low vibration performance of the cryostat is demonstrated with a two-stage vibration isolation, and the vibration suppression is optimized by tuning the mixing ratio of the gas–liquid-helium. With this technique, the linear power spectral densities of vibrations at certain frequencies higher than tens of hertz are suppressed by two orders of magnitude in all directions.

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Ultra-stable cryogenic sapphire cavity laser with an instability reaching 2 × 10−16 based on a low vibration level cryostat

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Ultra-stable cryogenic sapphire cavity laser with an instability reaching 2 × 10⁻¹⁶ based on a low vibration level cryostat