Spatiotemporal control of liquid crystal structure and dynamics through activity patterning

Rui Zhang; Steven A. Redford; Paul V. Ruijgrok; Nitin Kumar; Ali Mozaffari; Sasha Zemsky; Aaron R. Dinner; Vincenzo Vitelli; Zev Bryant; Margaret L. Gardel; Juan J. de Pablo

doi:10.1038/s41563-020-00901-4

Spatiotemporal control of liquid crystal structure and dynamics through activity patterning

Rui Zhang, Steven A. Redford, Paul V. Ruijgrok, Nitin Kumar, Ali Mozaffari, Sasha Zemsky, Aaron R. Dinner, Vincenzo Vitelli, Zev Bryant, Margaret L. Gardel^*, Juan J. de Pablo^*

^*Corresponding author for this work

Department of Physics

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

111 Citations (Scopus)

Abstract

Active materials are capable of converting free energy into mechanical work to produce autonomous motion, and exhibit striking collective dynamics that biology relies on for essential functions. Controlling those dynamics and transport in synthetic systems has been particularly challenging. Here, we introduce the concept of spatially structured activity as a means of controlling and manipulating transport in active nematic liquid crystals consisting of actin filaments and light-sensitive myosin motors. Simulations and experiments are used to demonstrate that topological defects can be generated at will and then constrained to move along specified trajectories by inducing local stresses in an otherwise passive material. These results provide a foundation for the design of autonomous and reconfigurable microfluidic systems where transport is controlled by modulating activity with light.

Original language	English
Pages (from-to)	875-882
Number of pages	8
Journal	Nature Materials
Volume	20
Issue number	6
DOIs	https://doi.org/10.1038/s41563-020-00901-4
Publication status	Published - Jun 2021

Bibliographical note

Publisher Copyright:
© 2020, The Author(s), under exclusive licence to Springer Nature Limited.

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title = "Spatiotemporal control of liquid crystal structure and dynamics through activity patterning",

abstract = "Active materials are capable of converting free energy into mechanical work to produce autonomous motion, and exhibit striking collective dynamics that biology relies on for essential functions. Controlling those dynamics and transport in synthetic systems has been particularly challenging. Here, we introduce the concept of spatially structured activity as a means of controlling and manipulating transport in active nematic liquid crystals consisting of actin filaments and light-sensitive myosin motors. Simulations and experiments are used to demonstrate that topological defects can be generated at will and then constrained to move along specified trajectories by inducing local stresses in an otherwise passive material. These results provide a foundation for the design of autonomous and reconfigurable microfluidic systems where transport is controlled by modulating activity with light.",

author = "Rui Zhang and Redford, \{Steven A.\} and Ruijgrok, \{Paul V.\} and Nitin Kumar and Ali Mozaffari and Sasha Zemsky and Dinner, \{Aaron R.\} and Vincenzo Vitelli and Zev Bryant and Gardel, \{Margaret L.\} and \{de Pablo\}, \{Juan J.\}",

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year = "2021",

month = jun,

doi = "10.1038/s41563-020-00901-4",

language = "English",

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AU - Zhang, Rui

AU - Redford, Steven A.

AU - Ruijgrok, Paul V.

AU - Kumar, Nitin

AU - Mozaffari, Ali

AU - Zemsky, Sasha

AU - Dinner, Aaron R.

AU - Vitelli, Vincenzo

AU - Bryant, Zev

AU - Gardel, Margaret L.

AU - de Pablo, Juan J.

PY - 2021/6

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N2 - Active materials are capable of converting free energy into mechanical work to produce autonomous motion, and exhibit striking collective dynamics that biology relies on for essential functions. Controlling those dynamics and transport in synthetic systems has been particularly challenging. Here, we introduce the concept of spatially structured activity as a means of controlling and manipulating transport in active nematic liquid crystals consisting of actin filaments and light-sensitive myosin motors. Simulations and experiments are used to demonstrate that topological defects can be generated at will and then constrained to move along specified trajectories by inducing local stresses in an otherwise passive material. These results provide a foundation for the design of autonomous and reconfigurable microfluidic systems where transport is controlled by modulating activity with light.

AB - Active materials are capable of converting free energy into mechanical work to produce autonomous motion, and exhibit striking collective dynamics that biology relies on for essential functions. Controlling those dynamics and transport in synthetic systems has been particularly challenging. Here, we introduce the concept of spatially structured activity as a means of controlling and manipulating transport in active nematic liquid crystals consisting of actin filaments and light-sensitive myosin motors. Simulations and experiments are used to demonstrate that topological defects can be generated at will and then constrained to move along specified trajectories by inducing local stresses in an otherwise passive material. These results provide a foundation for the design of autonomous and reconfigurable microfluidic systems where transport is controlled by modulating activity with light.

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DO - 10.1038/s41563-020-00901-4

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JO - Nature Materials

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Spatiotemporal control of liquid crystal structure and dynamics through activity patterning

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