声致发光气泡中高能量密度过程的研究

S. Putterman, Seth Pree
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引用次数: 1

摘要

水中驻声波中的气泡脉动的能量如此之大,以至于当它的最小半径接近时,气泡内部经历了向致密等离子体的一级相变。黑体辐射脉冲的温度范围从6000 k到20000 k,这取决于气泡内的气体。迄今为止,在水、硫酸和磷酸中进行的声致发光实验得出了相似的黑体温度。这些液体是氢键的,所以问题是它们的可压缩性是否限制了声致发光的能量集中。在最邻近的电子壳层之间有排斥力的液体,如小离子熔板,应该更不可压缩。由声辐射引起的能量损失的标度律估计;剪切粘度和周围流体的可压缩性将被讨论,目的是预测一种全新的声致发光机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards higher energy density processes in sonoluminescing bubbles
A bubble in a standing sound wave in water pulsates with such power that, as its minimum radius is approached, the interior undergoes a first order phase transition to a dense plasma. A pulse of blackbody radiation is emitted with temperatures ranging from 6,000K to 20,000K depending on the gas inside the bubble. To date experiments on sonoluminescence inside water, sulfuric acid and phosphoric acid have yielded similar blackbody temperatures. These liquids are hydrogen bonded and so the question arises as to whether their compressibility limits the energy concentration achieved by Sonoluminescence. Liquids where repulsion between nearest neighbor electron shells \such as small ion molten slats\ should be more incompressible. Scaling law estimates of the energy loss due to: acoustic radiation; shear viscosity, and compressibility of the surrounding fluid will be discussed with the goal of predicting a fundamentally new regime of sonoluminescence.
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