High-energy, stable single-frequency Ho:YAG ceramic amplifier system

We demonstrate a 2090 nm single-frequency, high-energy, Q-switched Ho:YAG ceramic master oscillator and power amplifier system that contains two-stage amplifiers. The maximum single-frequency pulse energy is 55.64 mJ at a pulse repetition frequency of 200 Hz. The half-width of the pulse spectrum is...

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Veröffentlicht in:	Applied optics (2004) 2017-12, Vol.56 (34), p.9531-9535
Hauptverfasser:	Zhang, Yixuan, Gao, Chunqing, Wang, Qing, Na, QuanXin, Gao, Mingwei, Zhang, Meng, Ye, Qing, Wang, YuJia, Zhang, Jian
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container_end_page	9535
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container_title	Applied optics (2004)
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creator	Zhang, Yixuan Gao, Chunqing Wang, Qing Na, QuanXin Gao, Mingwei Zhang, Meng Ye, Qing Wang, YuJia Zhang, Jian
description	We demonstrate a 2090 nm single-frequency, high-energy, Q-switched Ho:YAG ceramic master oscillator and power amplifier system that contains two-stage amplifiers. The maximum single-frequency pulse energy is 55.64 mJ at a pulse repetition frequency of 200 Hz. The half-width of the pulse spectrum is measured to be 3.96 MHz by a heterodyne technique. To the best of our knowledge, 55.64 mJ is the highest single-frequency output energy obtained from the Ho:YAG laser.
doi_str_mv	10.1364/AO.56.009531
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title	High-energy, stable single-frequency Ho:YAG ceramic amplifier system
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