Resonant Ring with a Gain of 36 for Use with a 1 MW 110 GHz Gyrotron

IF 1.8 3区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Journal of Infrared, Millimeter, and Terahertz Waves Pub Date : 2024-05-31 DOI:10.1007/s10762-024-00991-0
Elliot L. Claveau, Michael A. Shapiro, Richard J. Temkin
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Abstract

A 110 GHz quasi-optical ring resonator, designed for use with a 1 MW pulsed gyrotron, has been built and successfully tested using a 100 mW solid-state source. A low reflectance (2.4%) input coupler and a low-loss, four-mirror ring demonstrated a compression ratio, defined as the ratio of output to input power, of 36. The 6 ns output pulses were generated from the 2 m length ring using a silicon laser-driven semiconductor switch (LDSS). The quasi-optical ring resonator was designed with large waist sizes so that input pulses of up to 1 MW will stay under the 35 kV/cm electric field limit for ionization in ambient air. Maximum compression gain was achieved by matching the input coupling fraction to the round trip loss in the ring, achieving close to critical coupling. The experimental output pulse shape obtained after firing the LDSS was modeled using the reflectance, transmittance, and absorptance of the switch vs. time and vs. laser pulse fluence, with good agreement found with theory. The timing for the peak energy efficiency of 32% was found and the main loss mechanism limiting that efficiency was found to be the absorptance in the silicon wafer.

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增益为 36 的谐振环,用于 1 MW 110 GHz 陀螺仪
设计用于 1 兆瓦脉冲陀螺仪的 110 千兆赫准光环谐振器已经制作完成,并使用 100 毫瓦固态源成功进行了测试。低反射率(2.4%)输入耦合器和低损耗四镜环的压缩比(即输出功率与输入功率之比)达到了 36。6 毫微秒的输出脉冲是利用硅激光驱动半导体开关(LDSS)从 2 米长的环上产生的。准光学环形谐振器的设计具有较大的腰部尺寸,因此输入的高达 1 兆瓦的脉冲将保持在 35 kV/cm 的电场极限以下,以便在环境空气中实现电离。通过将输入耦合分数与环中的往返损耗相匹配,实现了最大的压缩增益,接近临界耦合。利用开关的反射率、透射率和吸收率与时间和激光脉冲能量的关系,对 LDSS 点火后获得的实验输出脉冲形状进行了建模,结果与理论十分吻合。我们找到了峰值能量效率为 32% 的时间,并发现限制该效率的主要损耗机制是硅晶片中的吸收率。
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来源期刊
Journal of Infrared, Millimeter, and Terahertz Waves
Journal of Infrared, Millimeter, and Terahertz Waves 工程技术-工程:电子与电气
CiteScore
6.20
自引率
6.90%
发文量
51
审稿时长
3 months
期刊介绍: The Journal of Infrared, Millimeter, and Terahertz Waves offers a peer-reviewed platform for the rapid dissemination of original, high-quality research in the frequency window from 30 GHz to 30 THz. The topics covered include: sources, detectors, and other devices; systems, spectroscopy, sensing, interaction between electromagnetic waves and matter, applications, metrology, and communications. Purely numerical work, especially with commercial software packages, will be published only in very exceptional cases. The same applies to manuscripts describing only algorithms (e.g. pattern recognition algorithms). Manuscripts submitted to the Journal should discuss a significant advancement to the field of infrared, millimeter, and terahertz waves.
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