Influence of optical surface distortion in a cylindrical Offner stretcher on the far-field signal-to-noise ratio

Bilong Hu; Wei Li; Wei Li; Yanlei Zuo; Yanlei Zuo; Zhaohui Wu; Zhaohui Wu; Zhaoli Li; Zhaoli Li; Jie Mu; Jie Mu; Xiao Wang; Xiao Wang; Xiaoming Zeng; Xiaoming Zeng

doi:10.1364/AO.501225

Applied Optics
Vol. 62,
Issue 28,
pp. 7544-7548
(2023)
•https://doi.org/10.1364/AO.501225

Influence of optical surface distortion in a cylindrical Offner stretcher on the far-field signal-to-noise ratio

Bilong Hu, Wei Li, Yanlei Zuo, Zhaohui Wu, Zhaoli Li, Jie Mu, Xiao Wang, and Xiaoming Zeng

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Bilong Hu, Wei Li, Yanlei Zuo, Zhaohui Wu, Zhaoli Li, Jie Mu, Xiao Wang, and Xiaoming Zeng, "Influence of optical surface distortion in a cylindrical Offner stretcher on the far-field signal-to-noise ratio," Appl. Opt. 62, 7544-7548 (2023)

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Abstract

In a stretcher, the surface distortion of the optical elements can introduce spectral phase modulations into the laser, which can affect the laser’s signal-to-noise ratio. In this paper, by combining ray tracing methods and angular spectrum diffraction methods, the impact of the mid-frequency surface distortion of the optical elements in an cylindrical Offner stretcher on the far-field signal-to-noise ratio of the laser is simulated. The results show that reducing the spatial chirp on the convex cylindrical mirror can effectively improve the far-field signal-to-noise ratio of the laser, and two methods to improve the far-field signal-to-noise ratio are presented.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Parameter	Symbol	Value	Parameter	Symbol	Value
Center wavelength	$λ_{0}$	910 nm	Time step	$δ t$	0.3 fs
FWHM bandwidth	$Δ λ$	140 nm	Number of time steps	$N_{t}$	$2^{17} - 1$
Passband width	$Δ λ_{p}$	220 nm	Beam aperture	$D$	5 mm
FWHM pulse width	$τ_{0}$	15 fs	Spatial step	$δ x$	16 µm
Line density of gratings	$d$	$1 / 1480 {m m}^{- 1}$	Number of spatial steps	$N_{s}$	$2^{10} - 1$
Curvature radius of CX	$R$	1500 mm	Incident angle on grating	$α$	63.9°
Spectrum shape	$n$	4th-order super-Gaussian	Distance between $G_{1}$ and $G_{2}$	$s$	507 mm

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Applied Optics