激光过热熔融二氧化硅出口表面激光损伤后喷射碎片的形貌

S. Demos, R. Negres, R. Raman, M. Feit, K. Manes, A. Rubenchik
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引用次数: 1

摘要

利用纳秒脉冲在透明介质材料的出口表面引发激光诱导损伤(击穿),使材料体积过热,局部温度达到1 eV,压力达到10 GPa或更大。这导致了物质的喷射和陨石坑的形成。这种过热材料的体积在很大程度上取决于激光的参数,如能量流和脉冲持续时间。为了阐明所涉及的材料行为,我们检查了喷出的过热材料颗粒的形态,并发现了独特的形态。我们假设这些形态是由每个粒子喷射时过热材料的结构和物理性质(如动态粘度和不稳定性)的差异引起的。喷射出的一些颗粒直径约为1 μ m,呈“液滴”状。另一个亚群似乎具有拉伸的泡沫状结构,可以将其描述为通过直径较小的柱相互连接的材料球体。这种颗粒表面通常含有纳米大小的纤维。在其他情况下,只有小球体被保存下来,这表明它们可能与泡沫结构在空气中移动时受到动压而坍塌有关。这些明显的特征源于在颗粒喷射之前的体积沸腾期间过热材料的结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Morphology of ejected debris from laser super-heated fused silica following exit surface laser-induced damage
Laser induced damage (breakdown) initiated on the exit surface of transparent dielectric materials using nanosecond pulses creates a volume of superheated material reaching localized temperatures on the order of 1 eV and pressures on the order of 10 GPa or larger. This leads to material ejection and the formation of a crater. The volume of this superheated material depends largely on the laser parameters such as fluence and pulse duration. To elucidate the material behaviors involved, we examined the morphologies of the ejected superheated material particles and found distinctive morphologies. We hypothesize that these morphologies arise from the difference in the structure and physical properties (such as the dynamic viscosity and presence of instabilities) of the superheated material at the time of ejection of each individual particle. Some of the ejected particles are on the order of 1 µm in diameter and appear as “droplets”. Another subgroup appears to have stretched, foam-like structure that can be described as material globules interconnected via smaller in diameter columns. Such particles often contain nanometer size fibers attached on their surface. In other cases, only the globules have been preserved suggesting that they may be associated with a collapsed foam structure under the dynamic pressure as it traverses in air. These distinct features originate in the structure of the superheated material during volume boiling just prior to the ejection of the particles.
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