The absorption of ultraintense, femtosecond laser pulses by a solid unleashes relativistic electrons, thereby creating a regime of relativistic optics. This has enabled exciting applications of relativistic particle beams and coherent X-ray radiation, and fundamental leaps in high energy density science and laboratory astrophysics. Obviously, central to these possibilities lies the basic problem of understanding and if possible, manipulating laser absorption. Surprisingly, the absorption of intense light largely remains an open question, despite the extensive variations in target and laser pulse structures. Moreover, there are only few experimental measurements of laser absorption carried out under very limited parameter ranges. Here we present an extensive investigation of absorption of intense 30 femtosecond laser pulses by solid metal targets. The study, performed under varying laser intensity and contrast ratio over four orders of magnitude, reveals a significant and non-intuitive dependence on these parameters. For contrast ratio of 10−9 and intensity of 2 × 1019 W cm−2, three observations are revealed: preferential acceleration of electrons along the laser axis, a ponderomotive scaling of electron temperature, and red shifting of emitted second-harmonic. These point towards the role of >J × >B absorption mechanism at relativistic intensity. The experimental results are supported by particle-in-cell simulations.
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机译:固体对超强飞秒激光脉冲的吸收释放出相对论电子,从而产生了相对论光学体系。这使得相对论粒子束和相干X射线辐射的激动人心的应用成为可能,并且在高能量密度科学和实验室天体物理学中取得了根本性的飞跃。显然,这些可能性的核心是理解的基本问题,如果可能的话,还需要操纵激光吸收。出乎意料的是,尽管目标和激光脉冲结构发生了巨大变化,但强光的吸收仍然是一个悬而未决的问题。而且,在非常有限的参数范围内进行激光吸收的实验测量很少。在这里,我们对固态金属靶标吸收30飞秒的强烈激光脉冲进行了广泛的研究。在变化的激光强度和对比度超过四个数量级的情况下进行的这项研究显示出对这些参数的显着且非直观的依赖性。对于10 −9 的对比度和2×10 19 W cm −2 的强度,揭示了三个观察结果:电子沿的优先加速激光轴,电子温度的惯性定标和发出的二次谐波的红移。这些指向相对论强度下的> J ×> B 吸收机制。实验结果得到细胞内颗粒模拟的支持。
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