Chemically active filaments: analysis and extensions of Slender Phoretic Theory

Panayiota Katsamba; Matthew Butler; Lyndon Koens; Tom Montenegro-Johnson

doi:10.1039/D2SM00942K

Chemically active filaments: analysis and extensions of Slender Phoretic Theory

Panayiota Katsamba, Matthew Butler, Lyndon Koens, Tom Montenegro-Johnson^*

^*Corresponding author for this work

Mathematics

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Abstract

Autophoretic microswimmers self-propel via surface interactions with a surrounding solute fuel. Chemically-active filaments are an exciting new microswimmer design that augments traditional autophoretic microswimmers, such as spherical Janus particles, with extra functionality inherent to their slender filament geometry. Slender Phoretic Theory (SPT) was developed by Katsamba et al. to analyse the dynamics of chemically-active filaments with arbitrary three-dimensional shape and chemical patterning. SPT provides a line integral solution for the solute concentration field and slip velocity on the filament surface. In this work, we exploit the generality of SPT to calculate a number of new, non-trivial analytical solutions for slender autophoretic microswimmers, including a general series solution for phoretic filaments with arbitrary geometry and surface chemistry, a universal solution for filaments with a straight centreline, and explicit solutions for some canonical shapes useful for practical applications and benchmarking numerical code. Many common autophoretic particle designs include discrete jumps in surface chemistry; here we extend our SPT to handle such discontinuities, showing that they are regularised by a boundary layer around the jump. Since our underlying framework is linear, combinations of our results provide a library of analytic solutions that will allow researchers to probe the interplay of activity patterning and shape.

Original language	English
Pages (from-to)	7051-7063
Journal	Soft Matter
Volume	18
Issue number	37
Early online date	23 Aug 2022
DOIs	https://doi.org/10.1039/D2SM00942K
Publication status	Published - 7 Oct 2022

Bibliographical note

Funding Information:
P. K. was supported in part by the Engineering and Physical Sciences Research Council (EPSRC) grant EP/R041555/1 “Artificial Transforming Swimmers for Precision Microfluidics Tasks” to T. M.-J. M. B. was supported by the Leverhulme Trust Research Leadership Award “Shape-Transforming Active Microfluidics” to T. M.-J. L. K. was funded by Australian Research Council (ARC) under the Discovery Early Career Research Award scheme (grant agreement DE200100168).

Publisher Copyright:
© 2022 The Royal Society of Chemistry.

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KatsambaP2022ChemicallyFinal published version, 0.99 MBLicence: Creative Commons: Attribution (CC BY)

1 Finished
1 Active

Shape-Transforming Active Microfluidics
Montenegro-Johnson, T.
Leverhulme Trust
1/12/20 → 30/11/25
Project: Research
Artificial Transforming Swimmers for Precision Microfluidics Tasks
Montenegro-Johnson, T.
Engineering & Physical Science Research Council
1/06/18 → 31/05/20
Project: Research Councils

Cite this

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abstract = "Autophoretic microswimmers self-propel via surface interactions with a surrounding solute fuel. Chemically-active filaments are an exciting new microswimmer design that augments traditional autophoretic microswimmers, such as spherical Janus particles, with extra functionality inherent to their slender filament geometry. Slender Phoretic Theory (SPT) was developed by Katsamba et al. to analyse the dynamics of chemically-active filaments with arbitrary three-dimensional shape and chemical patterning. SPT provides a line integral solution for the solute concentration field and slip velocity on the filament surface. In this work, we exploit the generality of SPT to calculate a number of new, non-trivial analytical solutions for slender autophoretic microswimmers, including a general series solution for phoretic filaments with arbitrary geometry and surface chemistry, a universal solution for filaments with a straight centreline, and explicit solutions for some canonical shapes useful for practical applications and benchmarking numerical code. Many common autophoretic particle designs include discrete jumps in surface chemistry; here we extend our SPT to handle such discontinuities, showing that they are regularised by a boundary layer around the jump. Since our underlying framework is linear, combinations of our results provide a library of analytic solutions that will allow researchers to probe the interplay of activity patterning and shape.",

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Chemically active filaments: analysis and extensions of Slender Phoretic Theory

Abstract

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Projects

Shape-Transforming Active Microfluidics

Artificial Transforming Swimmers for Precision Microfluidics Tasks

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