Advanced concepts for high-power, short-pulse CO2 laser development

SPIE Defense + Security Pub Date : 2016-06-07 DOI:10.1117/12.2223835

D. Gordon, V. Hasson, H. V. von Bergmann, Yu-Hsin Chen, A. Schmitt-Sody, J. Peñano

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引用次数: 5

Abstract

Ultra-short pulse lasers are dominated by solid-state technology, which typically operates in the near-infrared. Efforts to extend this technology to longer wavelengths are meeting with some success, but the trend remains that longer wavelengths correlate with greatly reduced power. The carbon dioxide (CO2) laser is capable of delivering high energy, 10 micron wavelength pulses, but the gain structure makes operating in the ultra-short pulse regime difficult. The Naval Research Laboratory and Air Force Research Laboratory are developing a novel CO2 laser designed to deliver ~1 Joule, ~1 picosecond pulses, from a compact gain volume (~2x2x80 cm). The design is based on injection seeding an unstable resonator, in order to achieve high energy extraction efficiency, and to take advantage of power broadening. The unstable resonator is seeded by a solid state front end, pumped by a custom built titanium sapphire laser matched to the CO2 laser bandwidth. In order to access a broader range of mid infrared wavelengths using CO2 lasers, one must consider nonlinear frequency multiplication, which is non-trivial due to the bandwidth of the 10 micron radiation.

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高功率、短脉冲CO2激光器开发的先进概念

超短脉冲激光器由固态技术主导，通常工作在近红外波段。将这项技术扩展到更长的波长的努力正在取得一些成功，但更长的波长与大大降低的功率相关的趋势仍然存在。二氧化碳(CO2)激光器能够提供高能量，10微米波长的脉冲，但增益结构使得在超短脉冲状态下操作困难。美国海军研究实验室和空军研究实验室正在开发一种新型的CO2激光器，设计用于从紧凑的增益体积(~2x2x80厘米)传输~1焦耳，~1皮秒脉冲。该设计是基于注入播种的不稳定谐振腔，以获得较高的能量提取效率，并利用功率展宽的优势。不稳定谐振腔由固态前端播种，由与CO2激光带宽相匹配的定制钛蓝宝石激光器泵浦。为了使用CO2激光器获得更宽范围的中红外波长，必须考虑非线性频率乘法，由于10微米辐射的带宽，这是非平凡的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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SPIE Defense + Security

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