Numerical study on growth and collapse of cloud cavitation in a focused ultrasound field

K. Okita
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引用次数: 1

Abstract

Acoustic cavitation is becoming increasingly important in therapeutic ultrasound applications. Nonlinear behavior as well as spatial distribution of cloud cavitation in a focused ultrasound field needs to be clarified to enhance the mechanical effects of cavitation on treatments such as lithotripsy and histotripsy. For this purpose, an ultrasound simulator treating cavitation has been developing. Since the distribution of the cloud cavitation generated in a focused ultrasound field results from the complex interactions between bubble oscillation and ultrasound, the bubble oscillation is strongly coupled with the focused ultrasound field. In addition, rectified diffusion, which plays an important role in the cavitation bubble growth, is taken into account. A focused ultrasound lithotripsy using the collapse of cloud cavitation was demonstrated numerically. The cloud cavitation is generated by the high frequency ultrasound waves and is collapsed by the low frequency ultrasound waves. As the result of the simulation, the cavitation bubble growth from nuclei around focus region in front of the model stone were reproduced. Then, the collapse of the cloud cavitation caused high pressure on the surface of the stone.Acoustic cavitation is becoming increasingly important in therapeutic ultrasound applications. Nonlinear behavior as well as spatial distribution of cloud cavitation in a focused ultrasound field needs to be clarified to enhance the mechanical effects of cavitation on treatments such as lithotripsy and histotripsy. For this purpose, an ultrasound simulator treating cavitation has been developing. Since the distribution of the cloud cavitation generated in a focused ultrasound field results from the complex interactions between bubble oscillation and ultrasound, the bubble oscillation is strongly coupled with the focused ultrasound field. In addition, rectified diffusion, which plays an important role in the cavitation bubble growth, is taken into account. A focused ultrasound lithotripsy using the collapse of cloud cavitation was demonstrated numerically. The cloud cavitation is generated by the high frequency ultrasound waves and is collapsed by the low frequency ultrasound waves. As the result of the si...
聚焦超声场中云空化生长与坍缩的数值研究
声空化在超声治疗中的应用越来越重要。云空化在聚焦超声场中的非线性行为和空间分布需要明确,以增强空化在碎石和组织切片等治疗中的力学作用。为此,研制了一种治疗空化的超声模拟器。由于超声聚焦场中产生的云空化分布是气泡振荡与超声复杂相互作用的结果,因此气泡振荡与超声聚焦场之间存在强耦合。此外,还考虑了在空化气泡生长过程中起重要作用的精流扩散。对利用云空化塌陷的聚焦超声碎石进行了数值模拟。云空化是由高频超声波产生的,被低频超声波坍缩。模拟结果再现了模型石前方聚焦区域周围的核形成空化气泡的过程。然后,云空化的崩塌对石头表面造成了高压。声空化在超声治疗中的应用越来越重要。云空化在聚焦超声场中的非线性行为和空间分布需要明确,以增强空化在碎石和组织切片等治疗中的力学作用。为此,研制了一种治疗空化的超声模拟器。由于超声聚焦场中产生的云空化分布是气泡振荡与超声复杂相互作用的结果,因此气泡振荡与超声聚焦场之间存在强耦合。此外,还考虑了在空化气泡生长过程中起重要作用的精流扩散。对利用云空化塌陷的聚焦超声碎石进行了数值模拟。云空化是由高频超声波产生的,被低频超声波坍缩。由于……
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