Sonoluminescence and sonochemistry

K. Suslick
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引用次数: 97

Abstract

The chemical effects of ultrasound originate from acoustic cavitation, which produces extremely energetic local transient conditions. In cavitating clouds of bubbles, both sonochemistry and sonoluminescence occur. Spectroscopic analysis of sonoluminescence from hydrocarbons and from metal carbonyls reveal temperatures of /spl sim/5000 K, /spl sim/1000 atm, with heating and cooling rates that exceed 10/sup 10/ K/s. Single bubble sonoluminescence produces much more symmetric bubble collapse with subsequently much higher effective temperatures during collapse. In cold liquids, bubble cloud cavitation is able to drive reactions that normally occur only under extreme conditions. Examples include activation of liquid-solid reactions and synthesis of amorphous and nanophase metals, and the synthesis of novel biomaterials, especially protein microspheres. Another remarkable phenomena occurs during ultrasonic irradiation of liquid-solid slurries: extremely high speed inter-particle collisions occur from cavitational shock waves at roughly half the speed of sound with effective temperatures of /spl sim/3000 K at the point of impact.
声致发光和声化学
超声的化学效应源于声空化,它产生了极具能量的局部瞬态条件。在空化的气泡云中,声化学和声致发光同时发生。碳氢化合物和金属羰基的声致发光光谱分析显示温度为/spl sim/5000 K和/spl sim/1000 atm,加热和冷却速度超过10/sup 10/ K/s。单泡声致发光产生更对称的气泡坍缩,随后在坍缩过程中产生更高的有效温度。在冷液体中,气泡云空化能够驱动通常只在极端条件下发生的反应。例子包括液固反应的激活和无定形和纳米相金属的合成,以及新型生物材料的合成,特别是蛋白质微球。超声辐照液固浆体时还会出现另一个显著现象:空化激波以大约一半声速,在撞击点有效温度为/spl sim/3000 K的情况下,产生极高速粒子间碰撞。
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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