Bjarne Vincent’s research while affiliated with Claude Bernard University Lyon 1 and other places

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Publications (1)


High-speed and acceleration micrometric jets induced by GHz streaming: A numerical study with direct numerical simulations
  • Article

April 2024

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44 Reads

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2 Citations

The Journal of the Acoustical Society of America

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Bjarne Vincent

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Gigahertz acoustic streaming enables the synthesis of localized microjets reaching speeds of up to meters per second, offering tremendous potential for precision micromanipulation. However, theoretical and numerical investigations of acoustic streaming at these frequencies remain so far relatively scarce due to significant challenges including: (i) the inappropriateness of classical approaches, rooted in asymptotic development, for addressing high-speed streaming with flow velocities comparable to the acoustic velocity; and (ii) the numerical cost of direct numerical simulations generally considered as prohibitive. In this paper, we investigate high-frequency bulk streaming using high-order finite difference direct numerical simulations. First, we demonstrate that high-speed micrometric jets of several meters per second can only be obtained at high frequencies, due to diffraction limits. Second, we establish that the maximum jet streaming speed at a given actuation power scales with the frequency to the power of 3/2 in the low attenuation limit and linearly with the frequency for strongly attenuated waves. Last, our analysis of transient regimes reveals a dramatic reduction in the time required to reach the maximum velocity as the frequency increases (power law in –5/2), leading to characteristic time on the order of μs at gigahertz frequencies, and hence accelerations within the Mega-g range.

Citations (1)


... The operating range makes it suitable for a new generation of hybrid systems, where acoustic waves are combined with photonic and electronics quantum nanodevices sharing similar, micrometric-sized footprints [44][45][46]. On a very general ground, the device characteristics can unveil interesting applications in several fields: from angular-momentum based optical communications [3,4,21], where ℓ-tuning and non-resonant light interaction are beneficial to applications, to topological acoustics [12] and acoustic tweezers [14,15], where it is possible to achieve chiral-based 4 degree of freedom particle manipulations [47] with the added features of operating at GHz frequencies, where accelerations as high as ∼ 10 6 g have been predicted for microjets in fluids [48]. ...

Reference:

Acousto-optic modulated vortex beam with tunable topological charge
High-speed and acceleration micrometric jets induced by GHz streaming: A numerical study with direct numerical simulations
  • Citing Article
  • April 2024

The Journal of the Acoustical Society of America