Phoretic flow induced by asymmetric confinement

Maciej Lisicki; Sébastien Michelin; Eric Lauga

doi:10.1017/jfm.2016.408

Phoretic flow induced by asymmetric confinement

Maciej Lisicki
, Sébastien Michelin
, Eric Lauga

Research output: Contribution to journal › Article › peer-review

Abstract

Internal phoretic flows due to the interactions of solid boundaries with local chemical gradients may be created using chemical patterning. Alternatively, we demonstrate here that internal flows might also be induced by geometric asymmetries of chemically homogeneous surfaces. We characterise the circulatory flow created in a cavity enclosed between two eccentric cylindrical walls of uniform chemical activity. Local gradients of the diffusing solute induce a slip flow along the surface of the cylinders, leading to a circulatory bulk flow pattern which can be solved analytically in the diffusive limit. The flow strength can be controlled by adjusting the relative positions of the cylinders, and an optimal configuration is identified. These results provide a model system for tunable phoretic pumps.

Original language	English
Pages (from-to)	R5
Journal	Journal of Fluid Mechanics
Volume	799
DOIs	https://doi.org/10.1017/jfm.2016.408
Publication status	Published - 25 Jul 2016

Keywords

biological fluid dynamics
low-Reynolds-number flows
micro-/nano-fluid dynamics

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10.1017/jfm.2016.408

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title = "Phoretic flow induced by asymmetric confinement",

abstract = "Internal phoretic flows due to the interactions of solid boundaries with local chemical gradients may be created using chemical patterning. Alternatively, we demonstrate here that internal flows might also be induced by geometric asymmetries of chemically homogeneous surfaces. We characterise the circulatory flow created in a cavity enclosed between two eccentric cylindrical walls of uniform chemical activity. Local gradients of the diffusing solute induce a slip flow along the surface of the cylinders, leading to a circulatory bulk flow pattern which can be solved analytically in the diffusive limit. The flow strength can be controlled by adjusting the relative positions of the cylinders, and an optimal configuration is identified. These results provide a model system for tunable phoretic pumps.",

keywords = "biological fluid dynamics, low-Reynolds-number flows, micro-/nano-fluid dynamics",

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AU - Lisicki, Maciej

AU - Michelin, Sébastien

AU - Lauga, Eric

PY - 2016/7/25

Y1 - 2016/7/25

N2 - Internal phoretic flows due to the interactions of solid boundaries with local chemical gradients may be created using chemical patterning. Alternatively, we demonstrate here that internal flows might also be induced by geometric asymmetries of chemically homogeneous surfaces. We characterise the circulatory flow created in a cavity enclosed between two eccentric cylindrical walls of uniform chemical activity. Local gradients of the diffusing solute induce a slip flow along the surface of the cylinders, leading to a circulatory bulk flow pattern which can be solved analytically in the diffusive limit. The flow strength can be controlled by adjusting the relative positions of the cylinders, and an optimal configuration is identified. These results provide a model system for tunable phoretic pumps.

AB - Internal phoretic flows due to the interactions of solid boundaries with local chemical gradients may be created using chemical patterning. Alternatively, we demonstrate here that internal flows might also be induced by geometric asymmetries of chemically homogeneous surfaces. We characterise the circulatory flow created in a cavity enclosed between two eccentric cylindrical walls of uniform chemical activity. Local gradients of the diffusing solute induce a slip flow along the surface of the cylinders, leading to a circulatory bulk flow pattern which can be solved analytically in the diffusive limit. The flow strength can be controlled by adjusting the relative positions of the cylinders, and an optimal configuration is identified. These results provide a model system for tunable phoretic pumps.

KW - biological fluid dynamics

KW - low-Reynolds-number flows

KW - micro-/nano-fluid dynamics

U2 - 10.1017/jfm.2016.408

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M3 - Article

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SN - 0022-1120

VL - 799

SP - R5

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

ER -

Phoretic flow induced by asymmetric confinement

Abstract

Keywords

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