激光-固体相互作用中扩展磁场的测量

J. Griff-McMahon, S. Malko, V. Valenzuela-Villaseca, C. A. Walsh, G. Fiksel, M. J. Rosenberg, D. B. Schaeffer, W. Fox
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引用次数: 0

摘要

利用质子射线成像方案和原位 X 射线靶标,对激光-箔片相互作用产生的磁场进行了高保真测量。与之前在类似实验条件下的发现不同,该技术揭示了自产生的比尔曼电池磁场在 t=+1.4 ns 时超出了膨胀等离子体羽流的边缘,半径超过 3.5 mm。对两个单能质子群的分析证实,质子偏转主要由远离相互作用(2 毫米)的磁场主导,而电场则微不足道。最先进的磁流体力学模拟无法捕捉到这些结果,这表明需要考虑激光-固体相互作用中磁场产生和传输的其他物理机制。
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Measurements of extended magnetic fields in laser-solid interaction
Magnetic fields generated from a laser-foil interaction are measured with high fidelity using a proton radiography scheme with in situ x-ray fiducials. In contrast to prior findings under similar experimental conditions, this technique reveals the self-generated, Biermann-battery fields extend beyond the edge of the expanding plasma plume to a radius of over 3.5 mm by t=+1.4 ns. An analysis of two monoenergetic proton populations confirms that proton deflection is dominated by magnetic fields far from the interaction (>2 mm) and electric fields are insignificant. The results are not captured in state-of-the-art magnetohydrodynamics simulations and suggest the need to consider additional physics mechanisms for the magnetic field generation and transport in laser-solid interactions.
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