Hydrodynamics of light levitated droplet evolution

Pengcheng Jiang; Yijing Yang; Rong Chen; Xun Zhu; Dingding Ye; Yang Yang; Hong Wang; Liang An; Qiang Liao

doi:10.1063/5.0198201

Hydrodynamics of light levitated droplet evolution

Pengcheng Jiang, Yijing Yang, Rong Chen, Xun Zhu, Dingding Ye, Yang Yang, Hong Wang, Liang An, Qiang Liao

Research output: Journal article publication › Journal article › Academic research › peer-review

1 Citation (Scopus)

Abstract

Light levitation of droplets over a locally heated gas-liquid interface by an infrared focus laser has been recently reported, but the hydrodynamics of light levitated droplet evolution remains unclear. Herein, we report that the condensed droplet experiences a periodic damped vortex motion process before evolving to a stably levitated droplet. In the later stage of the periodic damped vortex motion, the velocity decay rate is linearly proportional to the growth of condensed droplets. The linear scaling factor approximates the dynamic viscosity of the ambient fluid, which is analogous to the shear stress-shear relationship in the Newtonian friction law. This study deepens the understanding of the underlying mechanism of light levitated droplet evolution.

Original language	English
Article number	221601
Journal	Applied Physics Letters
Volume	124
Issue number	22
DOIs	https://doi.org/10.1063/5.0198201
Publication status	Published - 27 May 2024

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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10.1063/5.0198201

http://hdl.handle.net/10397/111075

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title = "Hydrodynamics of light levitated droplet evolution",

abstract = "Light levitation of droplets over a locally heated gas-liquid interface by an infrared focus laser has been recently reported, but the hydrodynamics of light levitated droplet evolution remains unclear. Herein, we report that the condensed droplet experiences a periodic damped vortex motion process before evolving to a stably levitated droplet. In the later stage of the periodic damped vortex motion, the velocity decay rate is linearly proportional to the growth of condensed droplets. The linear scaling factor approximates the dynamic viscosity of the ambient fluid, which is analogous to the shear stress-shear relationship in the Newtonian friction law. This study deepens the understanding of the underlying mechanism of light levitated droplet evolution.",

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T1 - Hydrodynamics of light levitated droplet evolution

AU - Jiang, Pengcheng

AU - Yang, Yijing

AU - Chen, Rong

AU - Zhu, Xun

AU - Ye, Dingding

AU - Yang, Yang

AU - Wang, Hong

AU - An, Liang

AU - Liao, Qiang

PY - 2024/5/27

Y1 - 2024/5/27

N2 - Light levitation of droplets over a locally heated gas-liquid interface by an infrared focus laser has been recently reported, but the hydrodynamics of light levitated droplet evolution remains unclear. Herein, we report that the condensed droplet experiences a periodic damped vortex motion process before evolving to a stably levitated droplet. In the later stage of the periodic damped vortex motion, the velocity decay rate is linearly proportional to the growth of condensed droplets. The linear scaling factor approximates the dynamic viscosity of the ambient fluid, which is analogous to the shear stress-shear relationship in the Newtonian friction law. This study deepens the understanding of the underlying mechanism of light levitated droplet evolution.

AB - Light levitation of droplets over a locally heated gas-liquid interface by an infrared focus laser has been recently reported, but the hydrodynamics of light levitated droplet evolution remains unclear. Herein, we report that the condensed droplet experiences a periodic damped vortex motion process before evolving to a stably levitated droplet. In the later stage of the periodic damped vortex motion, the velocity decay rate is linearly proportional to the growth of condensed droplets. The linear scaling factor approximates the dynamic viscosity of the ambient fluid, which is analogous to the shear stress-shear relationship in the Newtonian friction law. This study deepens the understanding of the underlying mechanism of light levitated droplet evolution.

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VL - 124

JO - Applied Physics Letters

JF - Applied Physics Letters

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Hydrodynamics of light levitated droplet evolution

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