Transition Radiation Field Enhanced Laser Proton Acceleration Employing Near-Critical-Density Foam
ID:164 View Protection:ATTENDEE Updated Time:2026-04-23 16:45:15 Hits:48 Poster Presentation

Start Time:Pending(Asia/Shanghai)

Duration:Pending

Session:No Session »

No files

Abstract
Laser-driven proton beams attract great interest in fields ranging from flash radiation oncology to compact accelerators. Increasing the proton energy is a critical prerequisite for advancing the practical applications of laser-driven proton sources. This study aims to elucidate the energy coupling mechanism between a direct-laser-acceleration electron beam and the proton accelerating field, with the goal of achieving enhanced proton acceleration. Utilizing an ultra-intense laser to irradiate a near-critical-density foam target, measurements are conducted of electrons, transition radiation, and protons. The experiments yielded a high-energy, high-charge electron beam, which triggers transition radiation in the terahertz band with an energy of up to 0.6 mJ. Concurrently, high-energy protons with a cutoff energy of 90 MeV is observed. Calculations reveal that in the near-field region behind the target rear surface, the energy associated with the transition radiation can generate an accelerating electric field of 1012–1013 V/m, capable of facilitating efficient proton acceleration. Further PIC simulations indicate that the relativistic electron beam provides the accelerating field predominantly via transition radiation. This electromagnetic wave field, superimposed on the plasma field, collectively drives proton acceleration. Based on these findings, a novel hybrid proton acceleration scheme, distinct from pure charge-separation field mechanisms, is proposed.
Keywords
laser proton acceleration,transition radiation field acceleration,relativistic electron beam,near critical density foam
Speaker
承宇 秦
博士后 中国科学院上海光学精密机械研究所

Submission Author
承宇 秦 中国科学院上海光学精密机械研究所
Submit Comment
Verify Code Change Another
All Comments
Important Date
  • May 12

    2026

    Conference Date

  • Apr 15 2026

    Draft paper submission deadline

  • May 12 2026

    Registration deadline

Sponsored By
National Key Laboratory of Plasma Physics, Laser Fusion Research Center, China Academy of Engineering Physics
Xiamen University