Ultra-intense vortex laser generation from a seed laser illuminated axial line-focused spiral zone plate

Zhang, Hao; Li, Qianni; Zheng, Chenglong; Zhao, Jie; Lu, Ying‐Hsin; Li, Dongao; Liu, Ke; Tian, Ye; Lin, Yuliang; Zhang, Fangpei; Yu, Tong-Pu

doi:10.1364/oe.467926

Opt. Express

2022

DOI: 10.1364/oe.467926

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Ultra-intense vortex laser generation from a seed laser illuminated axial line-focused spiral zone plate

Hao Zhang¹,

Qianni Li²,

Chenglong Zheng

et al.

Abstract: Relativistic vortex laser has drawn increasing attention in the laser-plasma community owing to its potential applications in various domains, e.g., generation of energetic charged particles with orbital angular momentum (OAM), high OAM X/γ-ray emission, high harmonics generation, and strong axial magnetic-field production. However, the generation of such relativistic vortex laser is still a challenge to the current laser technology. Using micro-structure targets named axial line-focused spiral zone plate (ALF… Show more

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2024

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Cited by 3 publications

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Proton acceleration driven by relativistic femtosecond Laguerre–Gaussian lasers

Wang

2024

Rev. Mod. Plasma Phys.

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With the advancement of ultra-intense and ultra-short laser technology, lasers have achieved new parameters in femtosecond (10–15 s) and petawatt (1015 W) ranges. Ion acceleration driven by these lasers has become a prominent research area. However, most research still relies on traditional Gaussian lasers, posing challenges in enhancing the low divergence angle, high flux, and high collimation of ion beams. This paper reviews a novel laser mode—the Laguerre–Gaussian (LG) laser in the relativistic domain. LG lasers feature a hollow intensity distribution and angular momentum, offering centripetal force and phase modulation at the axis center, reducing particle beam divergence and enabling focused acceleration. High-quality proton beams driven by ultra-intense, ultra-short LG lasers have promising applications in proton therapy, fast ignition in inertial confinement fusion, proton imaging, particle injection in accelerators, and astrophysics.

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Proton acceleration driven by relativistic femtosecond Laguerre–Gaussian lasers

Wang

2024

Rev. Mod. Plasma Phys.

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Mode conversion via reflected stepped phase plate in relativistic systems

Xie,

Wang,

Zhang

et al. 2024

AIP Advances

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The mode conversion efficiency (CE) of the relativistic Laguerre–Gaussian (LG) laser is researched in detail within the context of current petawatt laser facilities. The topological charge, radial integer, laser central wavelength, laser bandwidth, and the design of reflective phase plate are integrated into a unified equation in theory. It is found that the vortex laser mode can be expanded as a series of LG modes, with calculations indicating that the LG10 mode predominates, constituting ∼78% of the total mode distribution. Our analysis reveals that mode CE tends toward a saturation value as the number of steps of the reflective phase plate increases. The 32-step phase plate utilized in relativistic systems is fine enough to obtain a higher CE for LG10 mode lasers, which is also verified in three-dimensional particle-in-cell simulations. This research holds promise for optimizing the design of reflective phase plates to enhance the conversion efficiency of intense LG lasers, thereby facilitating broader applications in intense vortex laser technologies.

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Generation of ultra-intense vortex laser from a binary phase square spiral zone plate

Zhang,

Huang

et al. 2024

Opt. Express

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With the development of ultra-intense laser technology, the manipulation of relativistic laser pulses has become progressively challenging due to the limitations of damage thresholds for traditional optical devices. In recent years, the generation and manipulation of ultra-intense vortex laser pulses by plasma has attracted a great deal of attention. Here, we propose a new scheme to produce a relativistic vortex laser. This is achieved by using a relativistic Gaussian drive laser to irradiate a plasma binary phase square spiral zone plate (BPSSZP). Based on three-dimensional particle-in-cell (3D-PIC) simulations, we find that the drive laser has a phase difference of π after passing through the BPSSZP, ultimately generating the vortex laser with unique square symmetry. Quantitatively, by employing a drive laser pulse with intensity of 1.3 × 1018~W/cm2, a vortex laser with intensity up to 1.8 × 1019~W/cm2, and energy conversion efficiency of 18.61% can be obtained. The vortex lasers generated using the BPSSZP follow the modulo-4 transmutation rule when varying the topological charge of BPSSZP. Furthermore, the plasma-based BPSSZP has exhibited robustness and the ability to withstand multiple ultra-intense laser pulses. As the vortex laser generated via the BPSSZP has high intensity and large energy conversion efficiency, our scheme may hold potential applications in the community of laser-plasma, such as particles acceleration, intense high-order vortex harmonic generation, and vortex X/γ-ray sources.

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Ultra-intense vortex laser generation from a seed laser illuminated axial line-focused spiral zone plate

Cited by 3 publications

References 54 publications

Proton acceleration driven by relativistic femtosecond Laguerre–Gaussian lasers

Proton acceleration driven by relativistic femtosecond Laguerre–Gaussian lasers

Mode conversion via reflected stepped phase plate in relativistic systems

Generation of ultra-intense vortex laser from a binary phase square spiral zone plate

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