非理想真空中可达到的激光强度上限

Yitong Wu, L. Ji, Ruxin Li
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引用次数: 3

摘要

理想真空中激光场强的上限通常被认为是Schwinger场,对应于~10^29W/cm^2。我们在实际的非理想真空条件下研究了这种限制,发现从10^25W/cm^2开始出现强度抑制,当腔内剩余电子密度超过109cm^-^3时,出现1026W/cm^2的上限阈值。这是因为残余电子的存在引发了量子电动力学级联的雪崩,产生了大量的电子和正电子对。由于辐射反应,轻子进一步被困在驱动激光场中,这极大地消耗了激光能量。通过粒子池模拟和理论分析,给出了可达强度与真空度的关系。这些结果回答了当前真空条件下可实现光强的关键问题,并为未来100 - petawatt级激光器的发展提供了指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the upper limit of laser intensity attainable in nonideal vacuum
The upper limit of the laser field strength in perfect vacuum is usually considered as the Schwinger field, corresponding to ~10^29W/cm^2. We investigate such limitations under realistic non-ideal vacuum conditions and find out that intensity suppression appears starting from 10^25W/cm^2, showing an upper threshold at 1026W/cm^2 level if the residual electron density in chamber surpasses 109cm^-^3. This is because the presence of residual electrons triggers the avalanche of quantum-electrodynamics cascade that creates copious electron and positron pairs. The leptons are further trapped within the driving laser field due to radiation-reaction, which significantly depletes the laser energy. The relationship between the attainable intensity and the vacuity is given according to particle-in-cell simulations and theoretical analysis. These results answer a critical problem on the achievable light intensity based on present vacuum conditions and provide a guideline for future 100's-Petawatt class laser development.
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