In CPA, the pump amplifies the signal through an energy level gain medium system in which one of the transitions is non-radiative. This type of laser amplification has high efficiency from pump to signal and a relatively narrow gain bandwidth. In OPCPA, the pump amplifies the signal through parametric interaction while generating the idle wave. OPCPA can be broadband by manipulating the phase matching condition, but suffers from relatively low efficiency due to inverse conversion. QPCPA is a variation of OPCPA by dissipation of the idler with strong crystal absorption. The idler power dissipation hinders the inverse conversion effect, allowing for both high efficiency and wide bandwidth. Photo credit: Jingui Ma et al
Since the earliest demonstration of chirped-pulse amplification (CPA) and optical parametric chirped-pulse amplification (OPCPA), femtosecond lasers have been able to deliver ultra-high peak powers of up to ten petawatts (PW), paving the way for compact particle accelerators and X-ray sources.
To further increase peak powers, laser amplification schemes with both high conversion efficiency and wide bandwidth are needed. However, CPA laser amplifiers suffer from a relatively narrow gain bandwidth, while OPCPAs suffer from relatively low signal efficiency or pump depletion due to inverse conversion.
In a new article published in Light: Science & Applicationsa team of scientists led by Professor Liejia Qian from the Key Laboratory for Laser Plasmas (MOE), School of Physics and Astronomy, Shanghai Jiao Tong University, China, and collaborators have demonstrated an ultra-high-efficiency, low-noise scheme using quasi-parametric chirped -Pulse Amplification (QPCPA), a variation of OPCPA by dissipating the idler with strong crystal absorption.
The idler power dissipation hinders the inverse conversion effect, enabling QPCPA performance with high efficiency, wide bandwidth, and robustness to phase mismatch. They experimentally demonstrated 56% energy efficiency for an 810 nm signal converted by a 532 nm pump, or equivalently 85% pump depletion. Such record high depletion strongly suppressed superfluorescence parametric noise (PSF) in QPCPA to only ~10-6 relative to the amplified signal energy.
In their experiment, an 8 cm Sm:YCOB crystal with the orientation for maximized nonlinear coefficient was used, which was transparent to both pump and signal but opaque to the idler. Under a pumping intensity of 3 GW cm−2the highest signal efficiency of 56% was achieved at a seed intensity of ~7 MW cm−2which corresponds to a pump exhaustion of 85%.
The demonstrated depletion of the QPCPA pump was approximately 2.5 times that of OPCPA. The strong pump depletion through efficient signal amplification significantly suppressed the generation of PSF noise. Within the largest signal output of ~65 mJ, the measured PSF noise energy was as low as ~10 μJ. Pulse contrast after compression should be as high as ~109.
a, Schematic of the QPCPA scheme. The pump at 532 nm amplifies the signal at 810 nm and at the same time generates the idler at 1550 nm. The generated idler has an absorption through the doped rare earth ions Sm³⁺. b, pump-to-signal efficiency and pump depletion versus seed intensity at a pump intensity of ~3 GW cm⁻². c, Pulse profiles of the pump (black), amplified signal at seed intensities of 7 MW cm⁻² (solid red, point Ⅰ marked in b) and 2.5 W cm⁻² (dashed red, point Ⅱ marked in b). The shaded area shows the chirp pulse profile (spectrum) of the signal seed. The signal chirp is 40 ps nm⁻¹. d, Parametric superfluorescence energy (PSF) evolution (black squares and circles) and examined small-signal enhancement (blue circles). Photo credit: Jingui Ma et al
Prof. Ma, the first author, explained why they called such a method “quasi-parametric” amplification: “The QPCPA method is very interesting. In the saturated gain regime, its efficiency increases with seed intensity without inverse conversion, quite similar to ‘non-parametric’ laser gain. However, in the small-signal gain regime, it inherits all the parametric behaviors of OPCPA. The QPCPA combines the benefits of parametric and non-parametric processes.”
“Because the reverse conversion effect is completely impeded, the QPCPA is also robust to phase mismatch. This means that QPCPA is insensitive to variations in pump beam alignment and ambient temperature. This benefits QPCPA’s high repetition rate operation.” he added.
“With its very large efficiency-bandwidth product, the QPCPA scheme, based on a large Sm:YCOB crystal, can support up to 50 PW peak power using the same pump energy as current ten-petawatt laser systems, QPCPA may be a suitable candidate to push ultra-intensity lasers beyond the current ten petawatt limit,” said Prof. Ma.
The highest gain in tiny nanoscale devices
Jingui Ma et al., Demonstration of 85% pump depletion and 10-6 noise content in quasi-parametric chirped-pulse amplification, Light: Science & Applications (2022). DOI: 10.1038/s41377-022-00967-6
Provided by the Chinese Academy of Sciences
Citation: High efficiency and low noise amplification of ultrashort pulses by quasi-parametric amplification (2022, September 15), retrieved September 16, 2022 from https://phys.org/news/2022-09-high-efficiency-noise- amplification-ultrashort. html
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