Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials

K. Jiang; Z. G. Deng; T. W. Huang; K. J. Luo; P. Chen; M. Y. Yu; L. Xu; S. Li; L. Yang; F. Lu; W. W. Wang; Z. Q. Yuan; H. Peng; R. Li; H. Zhang; S. Z. Wu; H. B. Zhuo; W. Luo; W. M. Zhou; Y. Q. Gu; C. T. Zhou

doi:10.1103/yq7c-8bsv

Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials

K. Jiang
, Z. G. Deng
, T. W. Huang^*
, K. J. Luo
, P. Chen
, M. Y. Yu
, L. Xu
, S. Li
, L. Yang
, F. Lu
, W. W. Wang
, Z. Q. Yuan
, H. Peng
, R. Li
, H. Zhang
, S. Z. Wu
, H. B. Zhuo
, W. Luo
, W. M. Zhou^*
, Y. Q. Gu

C. T. Zhou

^*此作品的通讯作者

Shenzhen Technology University
China Academy of Engineering Physics
University of South China
Ministry of Education in China

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Energy loss of fast electrons in materials is a fundamental process in many fields spanning fusion research, high-energy-density physics, astrophysics, and material science. Contrary to conventional collisional theory that predicts greater energy loss in denser materials, we experimentally observe an anomalous phenomenon: high-current-density electron beams undergo significantly stronger deflection and stopping in low-average-density porous foams than in their denser counterparts. Pore-resolved simulations and theoretical analysis demonstrate that return currents along the foam’s skeleton generate multi-kilo-Tesla magnetic fields in the vacuum pores. These intense fields strongly scatter beam electrons, enhancing stopping by orders of magnitude beyond collisional predictions. The derived conditions for this anomalous stopping agree with experiments and simulations, establishing a new microstructure-mediated regime of beam-matter interaction with potential applications in charged-beam control for fusion and laboratory astrophysics.

源语言	英语
文章编号	185102
期刊	Physical Review Letters
卷	136
期	18
DOI	https://doi.org/10.1103/yq7c-8bsv
出版状态	已出版 - 8 5月 2026
已对外发布	是

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Jiang, K., Deng, Z. G., Huang, T. W., Luo, K. J., Chen, P., Yu, M. Y., Xu, L., Li, S., Yang, L., Lu, F., Wang, W. W., Yuan, Z. Q., Peng, H., Li, R., Zhang, H., Wu, S. Z., Zhuo, H. B., Luo, W., Zhou, W. M., ... Zhou, C. T. (2026). Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials. Physical Review Letters, 136(18), 文章 185102. https://doi.org/10.1103/yq7c-8bsv

@article{d5b46ba25e164dd09525f4fb7890cc53,

title = "Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials",

abstract = "Energy loss of fast electrons in materials is a fundamental process in many fields spanning fusion research, high-energy-density physics, astrophysics, and material science. Contrary to conventional collisional theory that predicts greater energy loss in denser materials, we experimentally observe an anomalous phenomenon: high-current-density electron beams undergo significantly stronger deflection and stopping in low-average-density porous foams than in their denser counterparts. Pore-resolved simulations and theoretical analysis demonstrate that return currents along the foam{\textquoteright}s skeleton generate multi-kilo-Tesla magnetic fields in the vacuum pores. These intense fields strongly scatter beam electrons, enhancing stopping by orders of magnitude beyond collisional predictions. The derived conditions for this anomalous stopping agree with experiments and simulations, establishing a new microstructure-mediated regime of beam-matter interaction with potential applications in charged-beam control for fusion and laboratory astrophysics.",

author = "K. Jiang and Deng, \{Z. G.\} and Huang, \{T. W.\} and Luo, \{K. J.\} and P. Chen and Yu, \{M. Y.\} and L. Xu and S. Li and L. Yang and F. Lu and Wang, \{W. W.\} and Yuan, \{Z. Q.\} and H. Peng and R. Li and H. Zhang and Wu, \{S. Z.\} and Zhuo, \{H. B.\} and W. Luo and Zhou, \{W. M.\} and Gu, \{Y. Q.\} and Zhou, \{C. T.\}",

note = "Publisher Copyright: {\textcopyright} 2026 American Physical Society.",

year = "2026",

month = may,

day = "8",

doi = "10.1103/yq7c-8bsv",

language = "English",

volume = "136",

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Jiang, K, Deng, ZG, Huang, TW, Luo, KJ, Chen, P, Yu, MY, Xu, L, Li, S, Yang, L, Lu, F, Wang, WW, Yuan, ZQ, Peng, H, Li, R, Zhang, H, Wu, SZ, Zhuo, HB, Luo, W, Zhou, WM, Gu, YQ & Zhou, CT 2026, 'Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials', Physical Review Letters, 卷 136, 号码 18, 185102. https://doi.org/10.1103/yq7c-8bsv

TY - JOUR

T1 - Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials

AU - Jiang, K.

AU - Deng, Z. G.

AU - Huang, T. W.

AU - Luo, K. J.

AU - Chen, P.

AU - Yu, M. Y.

AU - Xu, L.

AU - Li, S.

AU - Yang, L.

AU - Lu, F.

AU - Wang, W. W.

AU - Yuan, Z. Q.

AU - Peng, H.

AU - Li, R.

AU - Zhang, H.

AU - Wu, S. Z.

AU - Zhuo, H. B.

AU - Luo, W.

AU - Zhou, W. M.

AU - Gu, Y. Q.

AU - Zhou, C. T.

PY - 2026/5/8

Y1 - 2026/5/8

N2 - Energy loss of fast electrons in materials is a fundamental process in many fields spanning fusion research, high-energy-density physics, astrophysics, and material science. Contrary to conventional collisional theory that predicts greater energy loss in denser materials, we experimentally observe an anomalous phenomenon: high-current-density electron beams undergo significantly stronger deflection and stopping in low-average-density porous foams than in their denser counterparts. Pore-resolved simulations and theoretical analysis demonstrate that return currents along the foam’s skeleton generate multi-kilo-Tesla magnetic fields in the vacuum pores. These intense fields strongly scatter beam electrons, enhancing stopping by orders of magnitude beyond collisional predictions. The derived conditions for this anomalous stopping agree with experiments and simulations, establishing a new microstructure-mediated regime of beam-matter interaction with potential applications in charged-beam control for fusion and laboratory astrophysics.

AB - Energy loss of fast electrons in materials is a fundamental process in many fields spanning fusion research, high-energy-density physics, astrophysics, and material science. Contrary to conventional collisional theory that predicts greater energy loss in denser materials, we experimentally observe an anomalous phenomenon: high-current-density electron beams undergo significantly stronger deflection and stopping in low-average-density porous foams than in their denser counterparts. Pore-resolved simulations and theoretical analysis demonstrate that return currents along the foam’s skeleton generate multi-kilo-Tesla magnetic fields in the vacuum pores. These intense fields strongly scatter beam electrons, enhancing stopping by orders of magnitude beyond collisional predictions. The derived conditions for this anomalous stopping agree with experiments and simulations, establishing a new microstructure-mediated regime of beam-matter interaction with potential applications in charged-beam control for fusion and laboratory astrophysics.

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DO - 10.1103/yq7c-8bsv

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VL - 136

JO - Physical Review Letters

JF - Physical Review Letters

IS - 18

M1 - 185102

ER -

Experimental Observation of Anomalous Stopping of Mega-ampere Electron Current in Porous Materials

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