Introduction of Research Work on Laser Proton Acceleration and Its Application Carried out on Compact Laser–Plasma Accelerator at Peking University

Author:

Li Dongyu1ORCID,Yang Tang12,Wu Minjian12,Mei Zhusong12ORCID,Wang Kedong12,Lu Chunyang1,Zhao Yanying123,Ma Wenjun123ORCID,Zhu Kun123,Geng Yixing123,Yang Gen12ORCID,Xiao Chijie12,Chen Jiaer1,Lin Chen123,Tajima Toshiki4,Yan Xueqing123

Affiliation:

1. State Key Laboratory of Nuclear Physics and Technology & CAPT, Peking University, Beijing 100871, China

2. Beijing Laser Acceleration Innovation Center, Huairou District, Beijing 101400, China

3. Institute of Guangdong Laser Plasma Advanced Technology, Guangzhou 510540, China

4. Department of Physics and Astronomy, UC Irvine, Irvine, CA 92697, USA

Abstract

Laser plasma acceleration has made remarkable progress in the last few decades, but it also faces many challenges. Although the high gradient is a great potential advantage, the beam quality of the laser accelerator has a certain gap, or it is different from that of traditional accelerators. Therefore, it is important to explore and utilize its own features. In this article, some recent research progress on laser proton acceleration and its irradiation application, which was carried out on the compact laser plasma accelerator (CLAPA) platform at Peking University, have been introduced. By combining a TW laser accelerator and a monoenergetic beamline, proton beams with energies of less than 10 MeV, an energy spread of less than 1%, and with several to tens of pC charge, have been stably produced and transported in CLAPA. The beamline is an object–image point analyzing system, which ensures the transmission efficiency and the energy selection accuracy for proton beams with large initial divergence angle and energy spread. A spread-out Bragg peak (SOBP) is produced with high precision beam control, which preliminarily proved the feasibility of the laser accelerator for radiotherapy. Some application experiments based on laser-accelerated proton beams have also been carried out, such as proton radiograph, preparation of graphene on SiC, ultra-high dose FLASH radiation of cancer cells, and ion-beam trace probes for plasma diagnosis. The above applications take advantage of the unique characteristics of laser-driven protons, such as a micron scale point source, an ultra-short pulse duration, a wide energy spectrum, etc. A new laser-driven proton therapy facility (CLAPA II) is being designed and is under construction at Peking University. The 100 MeV proton beams will be produced via laser–plasma interaction by using a 2-PW laser, which may promote the real-world applications of laser accelerators in malignant tumor treatment soon.

Funder

Natural Science Foundation of China

National Grand Instrument Project

Beijing outstanding young scientists project, and ITER-CHINA program

Publisher

MDPI AG

Subject

Radiology, Nuclear Medicine and imaging,Instrumentation,Atomic and Molecular Physics, and Optics

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