Controlled surface-induced flows from the motion of self-assembled colloidal walkers

Charles E. Sing; Lothar Schmid; Matthias F. Schneider; Thomas Franke; Alfredo Alexander-Katza

doi:10.1073/pnas.0906489107

Controlled surface-induced flows from the motion of self-assembled colloidal walkers

Charles E. Sing, Lothar Schmid, Matthias F. Schneider, Thomas Franke, Alfredo Alexander-Katza

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

Abstract

Biological flows at the microscopic scale are important for the transport of nutrients, locomotion, and differentiation. Here, we present a unique approach for creating controlled, surface-induced flows inspired by a ubiquitous biological system, cilia. Our design is based on a collection of self-assembled colloidal rotors that "walk" along surfaces in the presence of a rotating magnetic field. These rotors are held together solely by magnetic forces that allow for reversible assembly and disassembly of the chains. Furthermore, rotation of the magnetic field allows for straightforward manipulation of the shape and motion of these chains. This system offers a simple and versatile approach for designing microfluidic devices as well as for studying fundamental questions in cooperative-driven motion and transport at the microscopic level.

Original language	English (US)
Pages (from-to)	535-540
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	107
Issue number	2
DOIs	https://doi.org/10.1073/pnas.0906489107
State	Published - 2010
Externally published	Yes

Keywords

Biological flows
Cilia
Magnetic
Microfluidics
Transport

ASJC Scopus subject areas

General

Online availability

10.1073/pnas.0906489107

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abstract = "Biological flows at the microscopic scale are important for the transport of nutrients, locomotion, and differentiation. Here, we present a unique approach for creating controlled, surface-induced flows inspired by a ubiquitous biological system, cilia. Our design is based on a collection of self-assembled colloidal rotors that {"}walk{"} along surfaces in the presence of a rotating magnetic field. These rotors are held together solely by magnetic forces that allow for reversible assembly and disassembly of the chains. Furthermore, rotation of the magnetic field allows for straightforward manipulation of the shape and motion of these chains. This system offers a simple and versatile approach for designing microfluidic devices as well as for studying fundamental questions in cooperative-driven motion and transport at the microscopic level.",

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AU - Schmid, Lothar

AU - Schneider, Matthias F.

AU - Franke, Thomas

AU - Alexander-Katza, Alfredo

PY - 2010

Y1 - 2010

N2 - Biological flows at the microscopic scale are important for the transport of nutrients, locomotion, and differentiation. Here, we present a unique approach for creating controlled, surface-induced flows inspired by a ubiquitous biological system, cilia. Our design is based on a collection of self-assembled colloidal rotors that "walk" along surfaces in the presence of a rotating magnetic field. These rotors are held together solely by magnetic forces that allow for reversible assembly and disassembly of the chains. Furthermore, rotation of the magnetic field allows for straightforward manipulation of the shape and motion of these chains. This system offers a simple and versatile approach for designing microfluidic devices as well as for studying fundamental questions in cooperative-driven motion and transport at the microscopic level.

AB - Biological flows at the microscopic scale are important for the transport of nutrients, locomotion, and differentiation. Here, we present a unique approach for creating controlled, surface-induced flows inspired by a ubiquitous biological system, cilia. Our design is based on a collection of self-assembled colloidal rotors that "walk" along surfaces in the presence of a rotating magnetic field. These rotors are held together solely by magnetic forces that allow for reversible assembly and disassembly of the chains. Furthermore, rotation of the magnetic field allows for straightforward manipulation of the shape and motion of these chains. This system offers a simple and versatile approach for designing microfluidic devices as well as for studying fundamental questions in cooperative-driven motion and transport at the microscopic level.

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Controlled surface-induced flows from the motion of self-assembled colloidal walkers

Abstract

Keywords

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