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Main Authors: Liu, Yangchun, Huang, Hairong, Wu, Dong, Hu, Tianxing, Xie, Huasheng, Liu, Bing, Sheng, Zhengmao, Dong, Jiaqi, Peng, Yueng-Kay Martin
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.02728
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author Liu, Yangchun
Huang, Hairong
Wu, Dong
Hu, Tianxing
Xie, Huasheng
Liu, Bing
Sheng, Zhengmao
Dong, Jiaqi
Peng, Yueng-Kay Martin
author_facet Liu, Yangchun
Huang, Hairong
Wu, Dong
Hu, Tianxing
Xie, Huasheng
Liu, Bing
Sheng, Zhengmao
Dong, Jiaqi
Peng, Yueng-Kay Martin
contents Energizing background ions plays a pivotal role in all forms of thermal nuclear fusion, as it can increase the fusion reaction rate without affecting the overall mechanical equilibrium. This is particularly critical for p11B fusion due to its exceptionally high operating temperature and substantial energy losses from bremsstrahlung radiation. Here, we report a nonlinear mechanism that efficiently transfers the energy of injected heating beams to background protons in p11B mixed plasmas, via fully kinetic Particle-In-Cell (PIC) simulations. When a proton neutral beam is injected into p11B plasmas, it triggers the excitation of ion Bernstein waves (IBWs) at harmonics of the proton cyclotron frequency. In the initial linear stage, the energy channels to background electrons and protons might be comparable, consistent with theoretical model for the energy transfer. However, in the latter nonlinear stage, the dominant channel transfers to background protons, generating a non-Maxwellian population of energetic protons. This transition is driven by a nonlinear spectral cascade of IBWs toward lower frequencies and longer wavelengths, which strengthens wave proton coupling while suppressing wave electron coupling.
format Preprint
id arxiv_https___arxiv_org_abs_2603_02728
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Energization of Proton via Beam-Driven Ion Bernstein Waves in p11B Plasmas
Liu, Yangchun
Huang, Hairong
Wu, Dong
Hu, Tianxing
Xie, Huasheng
Liu, Bing
Sheng, Zhengmao
Dong, Jiaqi
Peng, Yueng-Kay Martin
Plasma Physics
Energizing background ions plays a pivotal role in all forms of thermal nuclear fusion, as it can increase the fusion reaction rate without affecting the overall mechanical equilibrium. This is particularly critical for p11B fusion due to its exceptionally high operating temperature and substantial energy losses from bremsstrahlung radiation. Here, we report a nonlinear mechanism that efficiently transfers the energy of injected heating beams to background protons in p11B mixed plasmas, via fully kinetic Particle-In-Cell (PIC) simulations. When a proton neutral beam is injected into p11B plasmas, it triggers the excitation of ion Bernstein waves (IBWs) at harmonics of the proton cyclotron frequency. In the initial linear stage, the energy channels to background electrons and protons might be comparable, consistent with theoretical model for the energy transfer. However, in the latter nonlinear stage, the dominant channel transfers to background protons, generating a non-Maxwellian population of energetic protons. This transition is driven by a nonlinear spectral cascade of IBWs toward lower frequencies and longer wavelengths, which strengthens wave proton coupling while suppressing wave electron coupling.
title Energization of Proton via Beam-Driven Ion Bernstein Waves in p11B Plasmas
topic Plasma Physics
url https://arxiv.org/abs/2603.02728