Ultra-high intensity, ultrafast femtosecond lasers, with peak powers at a level of 10 petawatts (PW) or even higher, have led to the generation of unprecedented extreme physical conditions in laboratories, which pave new ways for the long-standing pursuit of fundamental science and the promising applications. The 100 PW laser system as the core mechanics of the Station of Extreme Light (SEL), one of the stations of Shanghai High repetition rate XFEL and Extreme light facility (SHINE), is being developed and scheduled to be ready in 2025. Here, we describe the recent progress of the front-end use in the SEL-100 PW laser facility. The results were published in Ultrafast Science on Jun 18, 2022.

In the front end, a 5.26 J / 0.1 Hz amplified output with a bandwidth over 200 nm near the center wavelength of 925 nm has been realized by our team, using 3 stages of optical parametric chirped-pulse amplification (OPCPA) based on lithium triborate (LBO) crystals (Figure. 1). After the compressor, we obtained a pulse duration of 13.4 fs by carefully dispersion compensation (Figure. 2). This OPCPA front end could potentially support a peak power of 263 TW at a repetition rate of 0.1 Hz. To the best of our knowledge, among all the 100-TW-level OPCPA systems, it shows the broadest spectral width, the shortest pulse duration, and the first OPCPA system working at a repetition-rate mode.

In the next stage, this front end, which can be regarded as a small prototype of the SEL-100 PW facility, will serve as the test platform for key technologies and optical components of the unique laser. The SEL-100 PW facility will open to users after being completed, and it can provide a focused beam intensity of more than 10²³ W/cm². This laser will work with a hard X-ray for pump-probe experiments, such as experimentally verifying the vacuum birefringence phenomenon.

Figure. 1. Schematic of the 263 TW/0.1 Hz OPCPA front end. (Image by SIOM)

Figure. 2. Characterization of compressed pulse. (a) Measured spectrum (black) and phase (red) of the 925 nm laser pulse. (b) Measured (yellow filled) and FTL (Fourier transform–limited, black solid) pulse duration of the compressed laser pulse. (Image by SIOM)

Article website:
https://doi.org/10.34133/2022/9894358

Contact:
WU Xiufeng
General Administrative Office
Shanghai Institute of Optics and Fine Mechanics, CAS
Email: xfwu@siom.ac.cn
Web: http://english.siom.cas.cn/