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Laser-driven proton acceleration beyond 100 MeV by radiation pressure and Coulomb repulsion in a conduction-restricted plasma

Yinren Shou, Xuezhi Wu, Ki Hong Pae, Gwang-Eun Ahn, Seung Yeon Kim, Seong Hoon Kim, Jin Woo Yoon, Jae Hee Sung, Seong Ku Lee, Zheng Gong, Xueqing Yan, Il Woo Choi, Chang Hee Nam

2025Nature Communications22 citationsDOIOpen Access PDF

Abstract

An ultrahigh-intensity femtosecond laser can establish a longitudinal electric field stronger than 1013 Vm−1 within a plasma, accelerating particles potentially to GeV over a sub-millimetre distance. Laser-accelerated protons with high brightness and picosecond duration are highly desired for applications including proton imaging and flash radiotherapy, while a major limitation is the relatively low proton energy achieved yet, primarily due to the lack of a controllable acceleration structure. Here, we report the generation of protons with a cutoff energy exceeding 110 MeV, achieved by irradiating a multi-petawatt femtosecond laser on a conduction-restricted nanometre polymer foil with a finite lateral size. The enduring obstacles in achieving ultrahigh laser contrast and excellent laser pointing accuracy were successfully overcome, allowing the effective utilization of size-reduced nanometre foils. A long acceleration structure could be maintained in such a quasi-isolated foil since the conduction of cold electrons was restricted and a strong Coulomb field was established by carbon ions. Our achievement paves the road to enhance proton energy further, well meeting the requirements for applications, through a controllable acceleration process using well-designed nano- or micro-structured targets. Laser-driven proton acceleration has faced a persistent 100-MeV energy barrier hindering its broader applications. Here, authors achieved the acceleration of protons beyond 110 MeV with an ultrahigh-contrast multi-petawatt laser pulse and a conduction-restricted nm-thick polymer foil.

Topics & Concepts

AccelerationProtonPlasmaRadiation pressureThermal conductionCoulombCoulomb explosionAtomic physicsPhysicsLaserRadiationNuclear physicsComputational physicsOpticsIonizationElectronClassical mechanicsIonQuantum mechanicsLaser-Plasma Interactions and DiagnosticsLaser-induced spectroscopy and plasmaPlanetary Science and Exploration
Laser-driven proton acceleration beyond 100 MeV by radiation pressure and Coulomb repulsion in a conduction-restricted plasma | Litcius