Fast Microscale Acoustic Streaming Driven by a Temperature-Gradient-Induced Nondissipative Acoustic Body Force

Wei Qiu; Jonas Helboe Joergensen; Enrico Corato; Henrik Bruus; Per Augustsson

doi:10.1103/PhysRevLett.127.064501

Fast Microscale Acoustic Streaming Driven by a Temperature-Gradient-Induced Nondissipative Acoustic Body Force

Wei Qiu, Jonas Helboe Joergensen, Enrico Corato, Henrik Bruus, Per Augustsson

Lund University

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Abstract

We study acoustic streaming in liquids driven by a nondissipative acoustic body force created by light-induced temperature gradients. This thermoacoustic streaming produces a velocity amplitude nearly 100 times higher than the boundary-driven Rayleigh streaming and the Rayleigh-Bénard convection at a temperature gradient of 10 K/mm in the channel. The Rayleigh streaming is altered by the acoustic body force at a temperature gradient of only 0.5 K/mm. The thermoacoustic streaming allows for modular flow control and enhanced heat transfer at the microscale. Our study provides the groundwork for studying microscale acoustic streaming coupled with temperature fields.

Original language	English
Article number	064501
Journal	Physical Review Letters
Volume	127
Issue number	6
Number of pages	6
ISSN	0031-9007
DOIs	https://doi.org/10.1103/PhysRevLett.127.064501
Publication status	Published - 2021

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title = "Fast Microscale Acoustic Streaming Driven by a Temperature-Gradient-Induced Nondissipative Acoustic Body Force",

abstract = "We study acoustic streaming in liquids driven by a nondissipative acoustic body force created by light-induced temperature gradients. This thermoacoustic streaming produces a velocity amplitude nearly 100 times higher than the boundary-driven Rayleigh streaming and the Rayleigh-B{\'e}nard convection at a temperature gradient of 10 K/mm in the channel. The Rayleigh streaming is altered by the acoustic body force at a temperature gradient of only 0.5 K/mm. The thermoacoustic streaming allows for modular flow control and enhanced heat transfer at the microscale. Our study provides the groundwork for studying microscale acoustic streaming coupled with temperature fields.",

author = "Wei Qiu and Joergensen, \{Jonas Helboe\} and Enrico Corato and Henrik Bruus and Per Augustsson",

note = "Publisher Copyright: {\textcopyright} 2021 American Physical Society.",

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doi = "10.1103/PhysRevLett.127.064501",

language = "English",

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AU - Qiu, Wei

AU - Joergensen, Jonas Helboe

AU - Corato, Enrico

AU - Bruus, Henrik

AU - Augustsson, Per

PY - 2021

Y1 - 2021

N2 - We study acoustic streaming in liquids driven by a nondissipative acoustic body force created by light-induced temperature gradients. This thermoacoustic streaming produces a velocity amplitude nearly 100 times higher than the boundary-driven Rayleigh streaming and the Rayleigh-Bénard convection at a temperature gradient of 10 K/mm in the channel. The Rayleigh streaming is altered by the acoustic body force at a temperature gradient of only 0.5 K/mm. The thermoacoustic streaming allows for modular flow control and enhanced heat transfer at the microscale. Our study provides the groundwork for studying microscale acoustic streaming coupled with temperature fields.

AB - We study acoustic streaming in liquids driven by a nondissipative acoustic body force created by light-induced temperature gradients. This thermoacoustic streaming produces a velocity amplitude nearly 100 times higher than the boundary-driven Rayleigh streaming and the Rayleigh-Bénard convection at a temperature gradient of 10 K/mm in the channel. The Rayleigh streaming is altered by the acoustic body force at a temperature gradient of only 0.5 K/mm. The thermoacoustic streaming allows for modular flow control and enhanced heat transfer at the microscale. Our study provides the groundwork for studying microscale acoustic streaming coupled with temperature fields.

U2 - 10.1103/PhysRevLett.127.064501

DO - 10.1103/PhysRevLett.127.064501

M3 - Journal article

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JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Fast Microscale Acoustic Streaming Driven by a Temperature-Gradient-Induced Nondissipative Acoustic Body Force

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