Deuteron-deuteron fusion in laser-driven counter-streaming collisionless plasmas

Xiaopeng Zhang; Jiarui Zhao; Dawei Yuan; Changbo Fu; Jie Bao; Liming Chen; Jianjun He; Long Hou; Liang Li; Yanfei Li; Yutong Li; Guoqian Liao; Yongjoo Rhee; Yang Sun; Shiwei Xu; Gang Zhao; Baojun Zhu; Jianqiang Zhu; Zhe Zhang; Jie Zhang

doi:10.1103/PhysRevC.96.055801

Deuteron-deuteron fusion in laser-driven counter-streaming collisionless plasmas

Xiaopeng Zhang
, Jiarui Zhao
, Dawei Yuan
, Changbo Fu
, Jie Bao
, Liming Chen
, Jianjun He
, Long Hou
, Liang Li
, Yanfei Li
, Yutong Li
, Guoqian Liao
, Yongjoo Rhee
, Yang Sun
, Shiwei Xu
, Gang Zhao
, Baojun Zhu
, Jianqiang Zhu
, Zhe Zhang
, Jie Zhang

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

18 Scopus citations

Abstract

Nuclear fusion reactions are the most important processes in nature to power stars and produce new elements, and lie at the center of the understanding of nucleosynthesis in the universe. It is critically important to study the reactions in full plasma environments that are close to true astrophysical conditions. By using laser-driven counter-streaming collisionless plasmas, the fusion d+d→3He+n is studied in a Gamow-like window around 27 keV. The results give hints that astrophysical nuclear reaction yields can be modulated significantly by the self-generated electromagnetic fields and the collective motion of the plasma. This plasma-version minicollider may provide a novel tool for studies of astrophysics-interested nuclear reactions, as well as a useful tool to constrain the models of plasma colliding dynamic.

Original language	English
Article number	055801
Journal	Physical Review C
Volume	96
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevC.96.055801
State	Published - 1 Nov 2017
Externally published	Yes

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10.1103/PhysRevC.96.055801

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title = "Deuteron-deuteron fusion in laser-driven counter-streaming collisionless plasmas",

abstract = "Nuclear fusion reactions are the most important processes in nature to power stars and produce new elements, and lie at the center of the understanding of nucleosynthesis in the universe. It is critically important to study the reactions in full plasma environments that are close to true astrophysical conditions. By using laser-driven counter-streaming collisionless plasmas, the fusion d+d→3He+n is studied in a Gamow-like window around 27 keV. The results give hints that astrophysical nuclear reaction yields can be modulated significantly by the self-generated electromagnetic fields and the collective motion of the plasma. This plasma-version minicollider may provide a novel tool for studies of astrophysics-interested nuclear reactions, as well as a useful tool to constrain the models of plasma colliding dynamic.",

author = "Xiaopeng Zhang and Jiarui Zhao and Dawei Yuan and Changbo Fu and Jie Bao and Liming Chen and Jianjun He and Long Hou and Liang Li and Yanfei Li and Yutong Li and Guoqian Liao and Yongjoo Rhee and Yang Sun and Shiwei Xu and Gang Zhao and Baojun Zhu and Jianqiang Zhu and Zhe Zhang and Jie Zhang",

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year = "2017",

month = nov,

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doi = "10.1103/PhysRevC.96.055801",

language = "英语",

volume = "96",

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TY - JOUR

T1 - Deuteron-deuteron fusion in laser-driven counter-streaming collisionless plasmas

AU - Zhang, Xiaopeng

AU - Zhao, Jiarui

AU - Yuan, Dawei

AU - Fu, Changbo

AU - Bao, Jie

AU - Chen, Liming

AU - He, Jianjun

AU - Hou, Long

AU - Li, Liang

AU - Li, Yanfei

AU - Li, Yutong

AU - Liao, Guoqian

AU - Rhee, Yongjoo

AU - Sun, Yang

AU - Xu, Shiwei

AU - Zhao, Gang

AU - Zhu, Baojun

AU - Zhu, Jianqiang

AU - Zhang, Zhe

AU - Zhang, Jie

PY - 2017/11/1

Y1 - 2017/11/1

N2 - Nuclear fusion reactions are the most important processes in nature to power stars and produce new elements, and lie at the center of the understanding of nucleosynthesis in the universe. It is critically important to study the reactions in full plasma environments that are close to true astrophysical conditions. By using laser-driven counter-streaming collisionless plasmas, the fusion d+d→3He+n is studied in a Gamow-like window around 27 keV. The results give hints that astrophysical nuclear reaction yields can be modulated significantly by the self-generated electromagnetic fields and the collective motion of the plasma. This plasma-version minicollider may provide a novel tool for studies of astrophysics-interested nuclear reactions, as well as a useful tool to constrain the models of plasma colliding dynamic.

AB - Nuclear fusion reactions are the most important processes in nature to power stars and produce new elements, and lie at the center of the understanding of nucleosynthesis in the universe. It is critically important to study the reactions in full plasma environments that are close to true astrophysical conditions. By using laser-driven counter-streaming collisionless plasmas, the fusion d+d→3He+n is studied in a Gamow-like window around 27 keV. The results give hints that astrophysical nuclear reaction yields can be modulated significantly by the self-generated electromagnetic fields and the collective motion of the plasma. This plasma-version minicollider may provide a novel tool for studies of astrophysics-interested nuclear reactions, as well as a useful tool to constrain the models of plasma colliding dynamic.

UR - https://www.scopus.com/pages/publications/85033699594

U2 - 10.1103/PhysRevC.96.055801

DO - 10.1103/PhysRevC.96.055801

M3 - 文章

AN - SCOPUS:85033699594

SN - 2469-9985

VL - 96

JO - Physical Review C

JF - Physical Review C

IS - 5

M1 - 055801

ER -

Deuteron-deuteron fusion in laser-driven counter-streaming collisionless plasmas

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