Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours

N. Yoshinaga; S. Yabunaka

doi:10.1039/9781788013499-00339

Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours

N. Yoshinaga, S. Yabunaka

Advanced Institute for Materials Research (AIMR)

Kyoto University

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

1 Citation (Scopus)

Abstract

In this chapter, we discuss the mechanism of self-propulsion using simple theoretical models. Particular focus is placed on the roles of hydrodynamic flow on self-propelled particles and drops. We also theoretically investigate self-propelled motion of chemically driven drops. The motion is driven by hydrodynamic flow resulting from the Marangoni effect and occurs for drops under an isotropic chemical reaction rather than under an anisotropic temperature and/or concentration gradient. This occurs even under the low Reynolds number in which fluid flow is described by the linear equations. We propose the mechanism of spontaneous symmetry breaking where hydrodynamics plays a significant role when coupled with nonlinear effects. We summarize the basic theoretical aspects of this phenomena including the reaction-diffusion equations and the hydrodynamic equation. We also discuss the collective behaviours of the drops by analysing the interaction between the self-propelled drops.

Original language	English
Title of host publication	Self-organized Motion
Subtitle of host publication	Physicochemical Design based on Nonlinear Dynamics
Editors	Istvan Lagzi, Veronique Pimienta, Nobuhiko J. Suematsu, Satoshi Nakata, Hiroyuki Kitahata
Publisher	Royal Society of Chemistry
Pages	339-365
Number of pages	27
Edition	14
DOIs	https://doi.org/10.1039/9781788013499-00339
Publication status	Published - 2019

Publication series

Name	RSC Theoretical and Computational Chemistry Series
Number	14
Volume	2019-January
ISSN (Print)	2041-3181
ISSN (Electronic)	2041-319X

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10.1039/9781788013499-00339

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Yoshinaga, N., & Yabunaka, S. (2019). Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours. In I. Lagzi, V. Pimienta, N. J. Suematsu, S. Nakata, & H. Kitahata (Eds.), Self-organized Motion: Physicochemical Design based on Nonlinear Dynamics (14 ed., pp. 339-365). (RSC Theoretical and Computational Chemistry Series; Vol. 2019-January, No. 14). Royal Society of Chemistry. https://doi.org/10.1039/9781788013499-00339

Yoshinaga, N. ; Yabunaka, S. / Chapter 14 : Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours. Self-organized Motion: Physicochemical Design based on Nonlinear Dynamics. editor / Istvan Lagzi ; Veronique Pimienta ; Nobuhiko J. Suematsu ; Satoshi Nakata ; Hiroyuki Kitahata. 14. ed. Royal Society of Chemistry, 2019. pp. 339-365 (RSC Theoretical and Computational Chemistry Series; 14).

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title = "Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours",

abstract = "In this chapter, we discuss the mechanism of self-propulsion using simple theoretical models. Particular focus is placed on the roles of hydrodynamic flow on self-propelled particles and drops. We also theoretically investigate self-propelled motion of chemically driven drops. The motion is driven by hydrodynamic flow resulting from the Marangoni effect and occurs for drops under an isotropic chemical reaction rather than under an anisotropic temperature and/or concentration gradient. This occurs even under the low Reynolds number in which fluid flow is described by the linear equations. We propose the mechanism of spontaneous symmetry breaking where hydrodynamics plays a significant role when coupled with nonlinear effects. We summarize the basic theoretical aspects of this phenomena including the reaction-diffusion equations and the hydrodynamic equation. We also discuss the collective behaviours of the drops by analysing the interaction between the self-propelled drops.",

author = "N. Yoshinaga and S. Yabunaka",

note = "Funding Information: The authors are grateful to T. Ohta and T. B. Liverpool for their helpful discussions. N.Y. acknowledges the support by Japan Society for the Promotion of Science (JSPS) KAKENHI Grants No. JP26800219, No. JP17K05605 and No. JP16H00793. S.Y. acknowledges the support JSPS KAKENHI Grant No. JP15K17737, Grants-in-Aid for JSPS Fellows (Grant No. 14J03111), and the JSPS Core-to-Core Program {\textquoteleft}Non-equilibrium dynamics of soft matter and information{\textquoteright}. Publisher Copyright: {\textcopyright} The Royal Society of Chemistry 2019.",

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language = "English",

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publisher = "Royal Society of Chemistry",

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Yoshinaga, N & Yabunaka, S 2019, Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours. in I Lagzi, V Pimienta, NJ Suematsu, S Nakata & H Kitahata (eds), Self-organized Motion: Physicochemical Design based on Nonlinear Dynamics. 14 edn, RSC Theoretical and Computational Chemistry Series, no. 14, vol. 2019-January, Royal Society of Chemistry, pp. 339-365. https://doi.org/10.1039/9781788013499-00339

Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours. / Yoshinaga, N.; Yabunaka, S.
Self-organized Motion: Physicochemical Design based on Nonlinear Dynamics. ed. / Istvan Lagzi; Veronique Pimienta; Nobuhiko J. Suematsu; Satoshi Nakata; Hiroyuki Kitahata. 14. ed. Royal Society of Chemistry, 2019. p. 339-365 (RSC Theoretical and Computational Chemistry Series; Vol. 2019-January, No. 14).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

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N1 - Funding Information: The authors are grateful to T. Ohta and T. B. Liverpool for their helpful discussions. N.Y. acknowledges the support by Japan Society for the Promotion of Science (JSPS) KAKENHI Grants No. JP26800219, No. JP17K05605 and No. JP16H00793. S.Y. acknowledges the support JSPS KAKENHI Grant No. JP15K17737, Grants-in-Aid for JSPS Fellows (Grant No. 14J03111), and the JSPS Core-to-Core Program ‘Non-equilibrium dynamics of soft matter and information’. Publisher Copyright: © The Royal Society of Chemistry 2019.

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Yoshinaga N, Yabunaka S. Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours. In Lagzi I, Pimienta V, Suematsu NJ, Nakata S, Kitahata H, editors, Self-organized Motion: Physicochemical Design based on Nonlinear Dynamics. 14 ed. Royal Society of Chemistry. 2019. p. 339-365. (RSC Theoretical and Computational Chemistry Series; 14). doi: 10.1039/9781788013499-00339

Chapter 14: Theory of Active Particles and Drops Driven by Chemical Reactions: The Role of Hydrodynamics on Self-propulsion and Collective Behaviours

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