辐射能量为 1 J 的高效脉冲射频激励感应放电 CO2 激光器

IF 0.8 4区 物理与天体物理 Q4 OPTICS
A. M. Razhev, E. S. Kargapol’tsev, I. A. Trunov
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引用次数: 0

摘要

摘要 首次研制出一种高效脉冲气体放电感应式 CO2 激光器,其辐射能量为 1.05 J。在这种情况下,激光辐射的脉冲持续时间约为 10 毫秒。辐射能量为 340 mJ 时,最大效率为 21.1%。高频电流脉冲沿着感应导体传播,从而形成感应放电,在 CO\(_{2}^{*}\) 分子的红外(IR)跃迁处产生种群反转。我们研究了感应式 CO2 激光辐射的时间和能量特性取决于泵浦脉冲的持续时间。对开发的激光器辐射的空间特性和光谱进行了估算。激光辐射的发散度为 0.52 mrad。激光输出光束的横截面直径约为 35 毫米。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Pulsed RF Excitation Inductive Discharge CO2 Laser with the Radiation Energy of 1 J and High Efficiency

Pulsed RF Excitation Inductive Discharge CO2 Laser with the Radiation Energy of 1 J and High Efficiency

An efficient pulsed gas-discharge inductive CO2-laser with a radiation energy of 1.05 J has been developed for the first time. In this case, the pulse duration of the laser radiation was about 10 ms. The maximum efficiency of 21.1% was obtained at a radiation energy of 340 mJ. HF current pulses propagated along the inductor conductor and, thus, an inductive discharge was formed to create a population inversion at the infrared (IR) transitions of CO\(_{2}^{*}\) molecules. The temporal and energy characteristics of the radiation of the inductive CO2-laser depending on the duration of the pump pulse are investigated. The spatial characteristics and spectrum of the radiation of the developed laser are estimated. The divergence of the laser radiation was 0.52 mrad. The cross-sectional dimension of the laser output beam was about 35 mm in diameter.

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来源期刊
Optics and Spectroscopy
Optics and Spectroscopy 物理-光谱学
CiteScore
1.60
自引率
0.00%
发文量
55
审稿时长
4.5 months
期刊介绍: Optics and Spectroscopy (Optika i spektroskopiya), founded in 1956, presents original and review papers in various fields of modern optics and spectroscopy in the entire wavelength range from radio waves to X-rays. Topics covered include problems of theoretical and experimental spectroscopy of atoms, molecules, and condensed state, lasers and the interaction of laser radiation with matter, physical and geometrical optics, holography, and physical principles of optical instrument making.
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