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Mechanisms of mass transfer to small spheres sinking in turbulence

Mechanisms of mass transfer to small spheres sinking in turbulence
Mechanisms of mass transfer to small spheres sinking in turbulence
Using laboratory experiments and numerical simulations, we examine the transfer of soluble material from small, spherical particles sinking in homogeneous turbulence at large Péclet number. A theoretical analysis predicts two distinct mechanisms of convective mass transfer: strain due to turbulence and slip due to gravitational settling. Their relative strength is parametrised by the sinking ratio, Sr = w0 τη/a, where w0 is the quiescent settling velocity, a is the particle radius and τη is the Kolmogorov timescale. This analysis predicts the topology of the concentration wake changes from a symmetric topology at Sr << 1 to an asymmetric topology at Sr >> 1 as the dominant mechanism of mass transfer changes. Particle tracking flow visualisations of small spheres releasing dye in turbulence confirm the existence of this change in mechanism at Sr = O(1). We complement these experiments with numerical simulations of the mass transfer from sinking particles. The transfer rate predicted by the simulation is found to be in good agreement with literature data for mass transfer to turbulent suspensions of solid particles and is consistent with asymptotic expressions for mass transfer in uniform flow when Sr >> 1. A decomposition of the convective fluxes confirms the transition in the transfer mechanism. At Sr = O(1), both mechanisms provide comparable contributions to transfer rate. Cross-correlation analysis reveals that particle-scale knowledge of both the recent strain and velocity history are required to predict the instantaneous transfer rate. Turbulence induced particle rotation has a modest suppression effect upon convective transfer by sinking.
0022-1120
Lawson, John
4e0b1895-51c5-41e6-9322-7f79e76e0e4c
Ganapathisubramani, Bharathram
5e69099f-2f39-4fdd-8a85-3ac906827052
Lawson, John
4e0b1895-51c5-41e6-9322-7f79e76e0e4c
Ganapathisubramani, Bharathram
5e69099f-2f39-4fdd-8a85-3ac906827052

Lawson, John and Ganapathisubramani, Bharathram (2023) Mechanisms of mass transfer to small spheres sinking in turbulence. Journal of Fluid Mechanics, 954, [A15]. (doi:10.1017/jfm.2022.998).

Record type: Article

Abstract

Using laboratory experiments and numerical simulations, we examine the transfer of soluble material from small, spherical particles sinking in homogeneous turbulence at large Péclet number. A theoretical analysis predicts two distinct mechanisms of convective mass transfer: strain due to turbulence and slip due to gravitational settling. Their relative strength is parametrised by the sinking ratio, Sr = w0 τη/a, where w0 is the quiescent settling velocity, a is the particle radius and τη is the Kolmogorov timescale. This analysis predicts the topology of the concentration wake changes from a symmetric topology at Sr << 1 to an asymmetric topology at Sr >> 1 as the dominant mechanism of mass transfer changes. Particle tracking flow visualisations of small spheres releasing dye in turbulence confirm the existence of this change in mechanism at Sr = O(1). We complement these experiments with numerical simulations of the mass transfer from sinking particles. The transfer rate predicted by the simulation is found to be in good agreement with literature data for mass transfer to turbulent suspensions of solid particles and is consistent with asymptotic expressions for mass transfer in uniform flow when Sr >> 1. A decomposition of the convective fluxes confirms the transition in the transfer mechanism. At Sr = O(1), both mechanisms provide comparable contributions to transfer rate. Cross-correlation analysis reveals that particle-scale knowledge of both the recent strain and velocity history are required to predict the instantaneous transfer rate. Turbulence induced particle rotation has a modest suppression effect upon convective transfer by sinking.

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Accepted/In Press date: 24 November 2022
e-pub ahead of print date: 3 January 2023
Published date: 3 January 2023

Identifiers

Local EPrints ID: 474485
URI: http://eprints.soton.ac.uk/id/eprint/474485
DOI: doi:10.1017/jfm.2022.998
ISSN: 0022-1120
PURE UUID: 7dc41511-10dd-47a1-8e08-bca00da5c5ef
ORCID for John Lawson: ORCID iD orcid.org/0000-0003-3260-3538
ORCID for Bharathram Ganapathisubramani: ORCID iD orcid.org/0000-0001-9817-0486

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Date deposited: 22 Feb 2023 22:34
Last modified: 10 Oct 2024 04:01

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Contributors

Author: John Lawson ORCID iD
Author: Bharathram Ganapathisubramani ORCID iD

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