A 0.5 Terawatt, 125 Femtosecond Ti:Sapphire Laser

Short-Wavelength Coherent Radiation: Generation and Application Pub Date : 1900-01-01 DOI:10.1364/swcr.1991.tua13

J. Kmetec, J. J. Macklin, B. Lemoff, J. Young

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引用次数: 1

Abstract

Broadband, high-energy storage, solid state amplifiers and chirped-pulse amplification further extend the peak power obtainable from a laser source. Laser-generation of x-rays and strong-field experiments require focusable beams at terawatt power levels. We have constructed a system at 802 nm using Ti:sapphire amplifiers and the technique of chirped-pulse amplification. In our system, a dye laser produces a train of 85 fsec seed pulses. A positively-dispersive grating pair expander chirps these pulses, stretching the pulsewidth to 180 psec while preserving the femtosecond bandwidth. The stretched pulses seed a Ti:sapphire regenerative amplifier, producing 8 mJ, 180 psec output. Further amplification in a triple-passed Ti:sapphire amplifier increases the pulse energy to 120 mJ. A negatively-dispersive parallel grating pair removes the chirp, recompressing the pulse to 125 fsec. The final output contains 60 mJ of energy in a 125 fsec pulsewidth. The output beam is Gaussian and measured to be 1.2 times diffraction limited. Focusing with an f/6 lens achieves 87% transmission through a 10.8 micron pinhole. Hence, f/6 focusing will produce 1018W/cm2. Passage through a saturable absorber reduces the amplifier noise to signal power ratio to 10−9 in the leading edge of the short pulse, with a large signal, whole beam transmission of 70%. Both the regenerative and the final amplifier are pumped by the 532 nm frequency-doubled output of a single commercially available 10 Hz Nd:YAG laser.

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一个0.5太瓦，125飞秒的钛蓝宝石激光器

宽带、高能存储、固态放大器和啁啾脉冲放大进一步扩展了从激光源获得的峰值功率。x射线的激光产生和强场实验需要太瓦功率水平的可聚焦光束。我们利用钛蓝宝石放大器和啁啾脉冲放大技术构建了一个802 nm的系统。在我们的系统中，染料激光器产生一列85秒的种子脉冲。一个正色散光栅对扩展器对这些脉冲进行啁啾，将脉冲宽度拉伸到180 psec，同时保持飞秒带宽。拉伸的脉冲种子一个钛蓝宝石再生放大器，产生8兆焦耳，180秒输出。进一步放大在三通钛蓝宝石放大器增加脉冲能量到120兆焦耳。一个负色散平行光栅对消除啁啾，重新压缩脉冲到125 fsec。最后的输出包含60兆焦耳的能量在一个125英尺秒的脉冲宽度。输出光束为高斯光束，是衍射极限的1.2倍。用f/6镜头对焦通过10.8微米的针孔达到87%的透射率。因此，f/6对焦将产生1018W/cm2。通过可饱和吸收器使放大器噪声与信号功率比在短脉冲前缘降至10−9，具有大信号，全波束传输70%。再生放大器和最终放大器都由单个商用10 Hz Nd:YAG激光器的532 nm倍频输出泵浦。

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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Short-Wavelength Coherent Radiation: Generation and Application

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