Fabrication of millimeter-scale crystal whispering gallery mode resonators

Applied Optics and Photonics China Pub Date : 2023-12-18 DOI:10.1117/12.3006429

Junhan Liu, Tianliang Qu, Changxin Xiong

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Abstract

The Whispering Gallery Modes Resonators(WGMR) are specific electromagnetic modes confined in circular resonators, where light beams are guided along the circumferences of the resonators with very small losses by total internal reflections. WGMR is the core component of optical filters, ultra-narrow linewidth laser, microwave photoelectric oscillator, optical frequency comb, rubidium atomic clock etc and high-precision sensors. Q factor is defined as the ratio of the total energy of photons in WGMR to the loss lost in one propagation cycle. The energy loss of WGMR is discussed. The cutting dynamics model diagram was established based the cutting force model for turning. The key technology affecting WGMR’s Q factor was the fabrication process. The manufacture of ultra-high Q factor WGMR are realized through rough machining, ultra-precision turning and precision polishing. The processing of ultra-precision turning and precision polishing is reported in the paper. The important fabrication processing of WGMR is ultra-precision turning. The test results show that the Q value of WGMR is 1.5×10 9@1550nm by Q value measurement system. The surface roughness and shape error of WGMR are 0.6nm (Ra value) and 5.3nm (PV value) respectively, measured by white light interferometer.

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制作毫米级晶体耳语画廊模式谐振器

耳语廊模式谐振器（WGMR）是局限在圆形谐振器中的特定电磁模式，光束沿着谐振器的圆周被引导，内部全反射的损耗非常小。WGMR 是光学滤波器、超窄线宽激光器、微波光电振荡器、光学频率梳、铷原子钟等和高精度传感器的核心部件。Q 因子的定义是光子在 WGMR 中的总能量与在一个传播周期中损失的能量之比。本文讨论了 WGMR 的能量损耗。在车削切削力模型的基础上建立了切削动力学模型图。影响 WGMR Q 因子的关键技术是制造工艺。超高 Q 值 WGMR 的制造是通过粗加工、超精密车削和精密抛光实现的。本文报告了超精密车削和精密抛光的加工过程。超精密车削是 WGMR 的重要制造工艺。测试结果表明，通过 Q 值测量系统，WGMR 的 Q 值为 1.5×10 9@1550nm。通过白光干涉仪测量，WGMR 的表面粗糙度和形状误差分别为 0.6nm （Ra 值）和 5.3nm（PV 值）。

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Applied Optics and Photonics China

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