Thermo-electron accumulation in light and heavy water during MHz-burst laser ablation

arXiv - PHYS - Plasma Physics Pub Date : 2024-09-05 DOI:arxiv-2409.03311

Denys Moskal, Jiri Martan, Vladislav Lang, Milan Honner

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Abstract

Laser-induced water ablation triggers various physical effects, including atom ionization, optical breakdown of the liquid, phase explosion, cavitation, and shockwave propagation. These effects can be further amplified in heavy water by deuterium-deuterium fusion reactions, which require extremely high energy levels. Laser pulses can be grouped in bursts to achieve the necessary energy within the ablation plasma plume. This study aims to compare the ablation plasma glow and thermal effects in light and heavy water under both single-pulse and burst-mode ultrashort laser irradiation. Notably, this research introduces the novel application of burst laser ablation in heavy water for the first time. The ablation was conducted beneath the water surface along a circular, laser-scanned trajectory, with two distinct ablation regimes: burst mode and single-pulse mode, utilizing lenses with varying focal lengths and different pulse durations. Absorption processes and plasma glow were monitored using visible and infrared detectors, a fast silicon detector, and a thermocouple. The study revealed that the burst regime in heavy water produced the most intense plasma glow when 1 ps laser pulses were used, with shorter pulses yielding less intense glow and the longest pulses yielding the least. Surprisingly, plasma glow at a lower initial power density of 2.6e13 W/cm2 was four times higher than at a higher power density of 8e13 W/cm2. These findings were compared with existing theories on plasma formation in water by ultrashort laser pulses. The observed increase in pulse-to-pulse plasma glow in burst mode was attributed to thermo-electron accumulation effects. The density of excited and hydrated electrons was calculated using both strong-field ionization and avalanche ionization models. Additionally, the influence of pulse parity on burst ablation glow in heavy water was discussed.

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兆赫脉冲激光烧蚀过程中轻水和重水中的热电子积累

激光诱导的水烧蚀会引发各种物理效应，包括原子电离、液体的光学击穿、相爆、空化和冲击波传播。在重水中，这些效应可通过氘-氘聚变反应进一步放大，而氘-氘聚变反应需要极高的能量水平。激光脉冲可以分组爆发，以便在烧蚀等离子体羽流中获得所需的能量。本研究旨在比较轻水和重水在单脉冲和脉冲串模式超短激光辐照下的烧蚀等离子体辉光和热效应。值得注意的是，这项研究首次在重水中引入了猝发激光烧蚀的新应用。烧蚀是在水面下沿着环形激光扫描轨迹进行的，有两种不同的烧蚀模式：猝发模式和单脉冲模式，利用的是不同焦距和不同脉冲持续时间的透镜。利用可见光和红外探测器、快速硅探测器和热电偶对吸收过程和等离子体辉光进行了监测。研究发现，当使用 1 ps 激光脉冲时，重水中的猝发机制产生的等离子体辉光最强烈，较短的脉冲产生的辉光强度较低，而最长的脉冲产生的辉光强度最低。令人惊讶的是，初始功率密度为 2.6e13 W/cm2 的较低等离子体辉光比功率密度为 8e13 W/cm2 的较高等离子体辉光高四倍。这些发现与现有的超短激光脉冲在水中形成等离子体的理论进行了比较。在猝发模式下观察到的脉冲间等离子体辉光的增加归因于热电子累积效应。利用强场电离和雪崩电离模型计算了激发电子和水合电子的密度。此外，还讨论了脉冲奇偶性对重水中爆发烧蚀辉光的影响。

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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arXiv - PHYS - Plasma Physics

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