Laser-driven Thomson scattering for the generation of ultra-bright multi-MeV gamma-ray beams

Europe Optics + Optoelectronics Pub Date : 2015-05-14 DOI:10.1117/12.2182569

G. Sarri, D. Corvan, J. Cole, W. Schumaker, A. Di Piazza, H. Ahmed, M. Yeung, Z. Zhao, C. Harvey, C. Keitel, K. Krushelnick, S. Mangles, Z. Najmudin, A. Thomas, M. Zepf

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引用次数: 1

Abstract

Compact γ-ray sources are of key importance not only for fundamental research but also for paramount practical applications such as cancer radiotherapy, active interrogation of materials, and high-energy radiography. Particular characteristics are required for meaningful implementation: multi-MeV energies per photon, a high degree of collimation, and a high peak brilliance. Laser-driven sources are theoretically expected to deliver such capabilities but experiments to date have reported either sub-MeV photon energies, or relatively low brilliance. By entering the non-linear regime of Thomson scattering, we report here on the first experimental realisation of a compact laser-driven γ-ray source that simultaneously ensures ultra-high brilliance (≈1019 photons s-1 mm-2 mrad-2 0.1% BW), low divergence (≈ mrad), and high photon energy (up to 18 MeV). The reported brilliance exceeds by two orders of magnitudes those of alternative mechanisms and it is the highest ever achieved in the multi-MeV regime in a laboratory experiment.

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激光驱动的汤姆逊散射产生超亮的多兆电子伏特伽马射线束

紧凑型γ射线源不仅对基础研究，而且对重要的实际应用，如癌症放射治疗、材料的主动询问和高能放射照相都具有重要意义。有意义的实现需要特殊的特性:每个光子的多兆电子伏能量，高度的准直，以及高峰值亮度。理论上，激光驱动的光源有望提供这样的能力，但迄今为止的实验报告要么是低于mev的光子能量，要么是相对较低的亮度。通过进入汤姆逊散射的非线性区域，我们在这里报告了一个紧凑的激光驱动γ射线源的第一个实验实现，同时保证了超高亮度(≈1019光子s-1 mm-2 mrad-2 0.1% BW)，低发散(≈mrad)和高光子能量(高达18 MeV)。报告的亮度超过了其他机制的两个数量级，是在实验室实验中在多兆电子伏特状态下达到的最高亮度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Europe Optics + Optoelectronics

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