Bandwidth expansion and pulse shape optimized for 10 PW laser design via spectral shaping

doi:10.1088/1674-1056/ac6018

Abstract We demonstrated a scheme of bandwidth expansion and pulse shape optimized to afford 10 PW laser design via spectral shaping, which uses the existing Nd:glass amplifier chain of the SG PW laser. Compared to the amplified pulse with a gain-narrowing effect, the required parameters of injected pulse energy, spectral bandwidth, and shape are analyzed, together with their influence on the system B-integral, energy output capability, and temporal intensity contrast. A bandwidth expansion to 7 nm by using LiNbO₃ birefringent spectral shaping resulted in an output energy of 2 kJ in a proof-of-principle experiment. The results are consistent with the theoretical prediction which suggests that the amplifier chain of SG PW laser is capable of achieving 6 kJ at the bandwidth of 7 nm and the B-integral < π . This will support a 10 PW laser with a compressed pulse energy of 4.8 kJ (efficiency=80%) at 480 fs.

Keywords: SG PW laser bandwidth expansion B-integral spectral shaping

Received: 30 December 2021
Revised: 10 March 2022
Accepted manuscript online: 23 March 2022

PACS:	42.40.My	(Applications)
	42.25.Lc	(Birefringence)
	42.15.Eq	(Optical system design)

Fund: Project supported by the International Partnership Program of Chinese Academy of Sciences (Grant No. 181231KYSB20170022) and the Natural Science Foundation of Jiangsu Higher Education Institutions of China (Grant No. 20KJB140020).

Corresponding Authors: Tao Wang, Xing-Qiang Lu
E-mail: twang@siom.ac.cn;xingqianglu@siom.ac.cn

Cite this article:

Da-Wei Li(李大为), Tao Wang(王韬), Xiao-Lei Yin(尹晓蕾), Li Wang(王利), Jia-Mei Li(李佳美),Hui Yu(余惠), Yong Cui(崔勇), Tian-Xiong Zhang(张天雄), Xing-Qiang Lu(卢兴强), and Guang Xu(徐光) Bandwidth expansion and pulse shape optimized for 10 PW laser design via spectral shaping 2022 Chin. Phys. B 31 094210

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