Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks

Hui Bo Tang; Yu Fei Hao; Guang Yue Hu; Quan Ming Lu; Chuang Ren; Yu Zhang; Ao Guo; Peng Hu; Yu Lin Wang; Xiang Bing Wang; Zhen Chi Zhang; Peng Yuan; Wei Liu; Hua Chong Si; Chun Kai Yu; Jia Yi Zhao; Jin Can Wang; Zhe Zhang; Xiao Hui Yuan; Da Wei Yuan; Zhi Yong Xie; Jun Xiong; Zhi Heng Fang; Jian Cai Xu; Jing Jing Ju; Guo Qiang Zhang; Jian Qiang Zhu; Ru Xin Li; Zhi Zhan Xu

doi:10.1126/sciadv.adn3320

Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks

Hui Bo Tang
, Yu Fei Hao
, Guang Yue Hu^*
, Quan Ming Lu^*
, Chuang Ren
, Yu Zhang
, Ao Guo
, Peng Hu
, Yu Lin Wang
, Xiang Bing Wang
, Zhen Chi Zhang
, Peng Yuan
, Wei Liu
, Hua Chong Si
, Chun Kai Yu
, Jia Yi Zhao
, Jin Can Wang
, Zhe Zhang
, Xiao Hui Yuan
, Da Wei Yuan

Zhi Yong Xie, Jun Xiong, Zhi Heng Fang, Jian Cai Xu, Jing Jing Ju, Guo Qiang Zhang, Jian Qiang Zhu, Ru Xin Li, Zhi Zhan Xu

^*Corresponding author for this work

University of Science and Technology of China
School of Physics, Harbin Institute of Technology
CAS - Purple Mountain Observatory
Chinese Academy of Sciences
CAS - Shanghai Institute of Optics and Fine Mechanics
University of Rochester
CAS - Institute of Physics
Shanghai Jiao Tong University
CAS - National Astronomical Observatories
Shanghai Institute of Laser Plasma

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Fermi acceleration is believed to be the primary mechanism to produce high-energy charged particles in the Universe, where charged particles gain energy successively from multiple reflections. Here, we present the direct laboratory experimental evidence of ion energization from single reflection off a supercritical collisionless shock, an essential component of Fermi acceleration, in a laser-produced magnetized plasma. A quasi-monoenergetic ion beam with two to four times the shock velocity was observed, which is consistent with the fast ion component observed in the Earth’s bow shock. Our simulations reproduced the energy gain and showed that ions were accelerated mainly by the motional electric field during reflection. The results identify shock drift acceleration as the dominant ion energization mechanism, which is consistent with satellite observation in the Earth’s bow shock. Our observations pave the way for laboratory investigations of the cosmic accelerators, also be beneficial to laser fusion and laser-driven ion accelerator.

Original language	English
Article number	eadn3320
Journal	Science Advances
Volume	11
Issue number	7
DOIs	https://doi.org/10.1126/sciadv.adn3320
State	Published - 14 Feb 2025
Externally published	Yes

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Tang, H. B., Hao, Y. F., Hu, G. Y., Lu, Q. M., Ren, C., Zhang, Y., Guo, A., Hu, P., Wang, Y. L., Wang, X. B., Zhang, Z. C., Yuan, P., Liu, W., Si, H. C., Yu, C. K., Zhao, J. Y., Wang, J. C., Zhang, Z., Yuan, X. H., ... Xu, Z. Z. (2025). Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks. Science Advances, 11(7), Article eadn3320. https://doi.org/10.1126/sciadv.adn3320

@article{b53720a36538443a8a974f4b2d76ac2b,

title = "Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks",

abstract = "Fermi acceleration is believed to be the primary mechanism to produce high-energy charged particles in the Universe, where charged particles gain energy successively from multiple reflections. Here, we present the direct laboratory experimental evidence of ion energization from single reflection off a supercritical collisionless shock, an essential component of Fermi acceleration, in a laser-produced magnetized plasma. A quasi-monoenergetic ion beam with two to four times the shock velocity was observed, which is consistent with the fast ion component observed in the Earth{\textquoteright}s bow shock. Our simulations reproduced the energy gain and showed that ions were accelerated mainly by the motional electric field during reflection. The results identify shock drift acceleration as the dominant ion energization mechanism, which is consistent with satellite observation in the Earth{\textquoteright}s bow shock. Our observations pave the way for laboratory investigations of the cosmic accelerators, also be beneficial to laser fusion and laser-driven ion accelerator.",

author = "Tang, \{Hui Bo\} and Hao, \{Yu Fei\} and Hu, \{Guang Yue\} and Lu, \{Quan Ming\} and Chuang Ren and Yu Zhang and Ao Guo and Peng Hu and Wang, \{Yu Lin\} and Wang, \{Xiang Bing\} and Zhang, \{Zhen Chi\} and Peng Yuan and Wei Liu and Si, \{Hua Chong\} and Yu, \{Chun Kai\} and Zhao, \{Jia Yi\} and Wang, \{Jin Can\} and Zhe Zhang and Yuan, \{Xiao Hui\} and Yuan, \{Da Wei\} and Xie, \{Zhi Yong\} and Jun Xiong and Fang, \{Zhi Heng\} and Xu, \{Jian Cai\} and Ju, \{Jing Jing\} and Zhang, \{Guo Qiang\} and Zhu, \{Jian Qiang\} and Li, \{Ru Xin\} and Xu, \{Zhi Zhan\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 The Authors, some rights reserved.",

year = "2025",

month = feb,

day = "14",

doi = "10.1126/sciadv.adn3320",

language = "英语",

volume = "11",

journal = "Science Advances",

issn = "2375-2548",

publisher = "American Association for the Advancement of Science",

number = "7",

}

Tang, HB, Hao, YF, Hu, GY, Lu, QM, Ren, C, Zhang, Y, Guo, A, Hu, P, Wang, YL, Wang, XB, Zhang, ZC, Yuan, P, Liu, W, Si, HC, Yu, CK, Zhao, JY, Wang, JC, Zhang, Z, Yuan, XH, Yuan, DW, Xie, ZY, Xiong, J, Fang, ZH, Xu, JC, Ju, JJ, Zhang, GQ, Zhu, JQ, Li, RX & Xu, ZZ 2025, 'Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks', Science Advances, vol. 11, no. 7, eadn3320. https://doi.org/10.1126/sciadv.adn3320

TY - JOUR

T1 - Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks

AU - Tang, Hui Bo

AU - Hao, Yu Fei

AU - Hu, Guang Yue

AU - Lu, Quan Ming

AU - Ren, Chuang

AU - Zhang, Yu

AU - Guo, Ao

AU - Hu, Peng

AU - Wang, Yu Lin

AU - Wang, Xiang Bing

AU - Zhang, Zhen Chi

AU - Yuan, Peng

AU - Liu, Wei

AU - Si, Hua Chong

AU - Yu, Chun Kai

AU - Zhao, Jia Yi

AU - Wang, Jin Can

AU - Zhang, Zhe

AU - Yuan, Xiao Hui

AU - Yuan, Da Wei

AU - Xie, Zhi Yong

AU - Xiong, Jun

AU - Fang, Zhi Heng

AU - Xu, Jian Cai

AU - Ju, Jing Jing

AU - Zhang, Guo Qiang

AU - Zhu, Jian Qiang

AU - Li, Ru Xin

AU - Xu, Zhi Zhan

PY - 2025/2/14

Y1 - 2025/2/14

N2 - Fermi acceleration is believed to be the primary mechanism to produce high-energy charged particles in the Universe, where charged particles gain energy successively from multiple reflections. Here, we present the direct laboratory experimental evidence of ion energization from single reflection off a supercritical collisionless shock, an essential component of Fermi acceleration, in a laser-produced magnetized plasma. A quasi-monoenergetic ion beam with two to four times the shock velocity was observed, which is consistent with the fast ion component observed in the Earth’s bow shock. Our simulations reproduced the energy gain and showed that ions were accelerated mainly by the motional electric field during reflection. The results identify shock drift acceleration as the dominant ion energization mechanism, which is consistent with satellite observation in the Earth’s bow shock. Our observations pave the way for laboratory investigations of the cosmic accelerators, also be beneficial to laser fusion and laser-driven ion accelerator.

AB - Fermi acceleration is believed to be the primary mechanism to produce high-energy charged particles in the Universe, where charged particles gain energy successively from multiple reflections. Here, we present the direct laboratory experimental evidence of ion energization from single reflection off a supercritical collisionless shock, an essential component of Fermi acceleration, in a laser-produced magnetized plasma. A quasi-monoenergetic ion beam with two to four times the shock velocity was observed, which is consistent with the fast ion component observed in the Earth’s bow shock. Our simulations reproduced the energy gain and showed that ions were accelerated mainly by the motional electric field during reflection. The results identify shock drift acceleration as the dominant ion energization mechanism, which is consistent with satellite observation in the Earth’s bow shock. Our observations pave the way for laboratory investigations of the cosmic accelerators, also be beneficial to laser fusion and laser-driven ion accelerator.

UR - https://www.scopus.com/pages/publications/85218220451

U2 - 10.1126/sciadv.adn3320

DO - 10.1126/sciadv.adn3320

M3 - 文章

C2 - 39937917

AN - SCOPUS:85218220451

SN - 2375-2548

VL - 11

JO - Science Advances

JF - Science Advances

IS - 7

M1 - eadn3320

ER -

Laboratory observation of ion drift acceleration via reflection off laser-produced magnetized collisionless shocks

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