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
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.
Topics & Concepts
Microscale chemistryAcoustic streamingAcousticsAcoustic waveMechanicsPhysicsMaterials scienceMathematics educationUltrasonic sensorMathematicsMicrofluidic and Bio-sensing TechnologiesAerodynamics and Acoustics in Jet FlowsMicrofluidic and Capillary Electrophoresis Applications