Saved in:
Bibliographic Details
Main Authors: Wang, Wenpeng, Sun, Xinyue, Sun, Fengyu, Lv, Zhengxing, Glize, K., Shi, Zhiyong, Xu, Yi, Zhang, Zongxin, Wu, Fenxiang, Hu, Jiabing, Qian, Jiayi, Zhu, Jiacheng, Liang, Xiaoyan, Leng, Yuxin, Li, Ruxin, Xu, Zhizhan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.12683
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910794253336576
author Wang, Wenpeng
Sun, Xinyue
Sun, Fengyu
Lv, Zhengxing
Glize, K.
Shi, Zhiyong
Xu, Yi
Zhang, Zongxin
Wu, Fenxiang
Hu, Jiabing
Qian, Jiayi
Zhu, Jiacheng
Liang, Xiaoyan
Leng, Yuxin
Li, Ruxin
Xu, Zhizhan
author_facet Wang, Wenpeng
Sun, Xinyue
Sun, Fengyu
Lv, Zhengxing
Glize, K.
Shi, Zhiyong
Xu, Yi
Zhang, Zongxin
Wu, Fenxiang
Hu, Jiabing
Qian, Jiayi
Zhu, Jiacheng
Liang, Xiaoyan
Leng, Yuxin
Li, Ruxin
Xu, Zhizhan
contents High-energy, high-flux collimated proton beams with high repetition rates are critical for applications such as proton therapy, proton radiography, high-energy-density matter generation, and compact particle accelerators. However, achieving proton beam collimation has typically relied on complex and expensive target fabrication or precise control of auxiliary laser pulses, which poses significant limitations for high-repetition applications. Here, we demonstrate an all-optical method for collimated proton acceleration using a single femtosecond Laguerre-Gaussian (LG) laser with an intensity exceeding 1020 W/cm2 irradiating a simple planar target. Compared to conventional Gaussian laser-driven schemes, the maximum proton energy is enhanced by 60% (reaching 35 MeV) and beam divergence is much reduced. Particle-in-cell simulations reveal that a plasma jet is initially focused by the hollow electric sheath field of the LG laser, and then electrons in the jet are further collimated by self-generated magnetic fields. This process amplifies the charge-separation electric field between electrons and ions, leading to increased proton energy in the longitudinal direction and improved collimation in the transverse direction. This single-LG-laser-driven collimation mechanism offers a promising pathway for high-repetition, high-quality proton beam generation, with broad potential applications including proton therapy and fast ignition in inertial confinement fusion.
format Preprint
id arxiv_https___arxiv_org_abs_2501_12683
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhanced Proton Acceleration via Petawatt Laguerre-Gaussian Lasers
Wang, Wenpeng
Sun, Xinyue
Sun, Fengyu
Lv, Zhengxing
Glize, K.
Shi, Zhiyong
Xu, Yi
Zhang, Zongxin
Wu, Fenxiang
Hu, Jiabing
Qian, Jiayi
Zhu, Jiacheng
Liang, Xiaoyan
Leng, Yuxin
Li, Ruxin
Xu, Zhizhan
Plasma Physics
High-energy, high-flux collimated proton beams with high repetition rates are critical for applications such as proton therapy, proton radiography, high-energy-density matter generation, and compact particle accelerators. However, achieving proton beam collimation has typically relied on complex and expensive target fabrication or precise control of auxiliary laser pulses, which poses significant limitations for high-repetition applications. Here, we demonstrate an all-optical method for collimated proton acceleration using a single femtosecond Laguerre-Gaussian (LG) laser with an intensity exceeding 1020 W/cm2 irradiating a simple planar target. Compared to conventional Gaussian laser-driven schemes, the maximum proton energy is enhanced by 60% (reaching 35 MeV) and beam divergence is much reduced. Particle-in-cell simulations reveal that a plasma jet is initially focused by the hollow electric sheath field of the LG laser, and then electrons in the jet are further collimated by self-generated magnetic fields. This process amplifies the charge-separation electric field between electrons and ions, leading to increased proton energy in the longitudinal direction and improved collimation in the transverse direction. This single-LG-laser-driven collimation mechanism offers a promising pathway for high-repetition, high-quality proton beam generation, with broad potential applications including proton therapy and fast ignition in inertial confinement fusion.
title Enhanced Proton Acceleration via Petawatt Laguerre-Gaussian Lasers
topic Plasma Physics
url https://arxiv.org/abs/2501.12683