Journal article
Falko Schmidt, Benno Liebchen, Hartmut Löwen, Giovanni Volpe
Journal of Chemical Physics, vol. 150(9), 2019 Feb 7, pp. 94905-94905
Journal of Chemical Physics, vol. 150(9), 2019 Feb 7, pp. 94905-94905
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Schmidt, F., Liebchen, B., Löwen, H., & Volpe, G. (2019). Light-controlled assembly of active colloidal molecules. Journal of Chemical Physics, 150(9), 94905–94905.
Chicago/Turabian
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Schmidt, Falko, Benno Liebchen, Hartmut Löwen, and Giovanni Volpe. “Light-Controlled Assembly of Active Colloidal Molecules.” Journal of Chemical Physics 150, no. 9 (February 7, 2019): 94905–94905.
MLA
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Schmidt, Falko, et al. “Light-Controlled Assembly of Active Colloidal Molecules.” Journal of Chemical Physics, vol. 150, no. 9, Feb. 2019, pp. 94905–05.
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@article{falko2019a,
title = {Light-controlled assembly of active colloidal molecules.},
year = {2019},
month = feb,
day = {7},
issue = {9},
journal = {Journal of Chemical Physics},
pages = {94905-94905},
volume = {150},
author = {Schmidt, Falko and Liebchen, Benno and Löwen, Hartmut and Volpe, Giovanni},
month_numeric = {2}
}
Abstract:
Thanks to a constant energy input, active matter can self-assemble into phases with complex architectures and functionalities such as living clusters that dynamically form, reshape, and break-up, which are forbidden in equilibrium materials by the entropy maximization (or free energy minimization) principle. The challenge to control this active self-assembly has evoked widespread efforts typically hinging on engineering of the properties of individual motile constituents. Here, we provide a different route, where activity occurs as an emergent phenomenon only when individual building blocks bind together in a way that we control by laser light. Using experiments and simulations of two species of immotile microspheres, we exemplify this route by creating active molecules featuring a complex array of behaviors, becoming migrators, spinners, and rotators. The possibility to control the dynamics of active self-assembly via light-controllable nonreciprocal interactions will inspire new approaches to understand living matter and to design active materials.
Thanks to a constant energy input, active matter can self-assemble into phases with complex architectures and functionalities such as living clusters that dynamically form, reshape, and break-up, which are forbidden in equilibrium materials by the entropy maximization (or free energy minimization) principle. The challenge to control this active self-assembly has evoked widespread efforts typically hinging on engineering of the properties of individual motile constituents. Here, we provide a different route, where activity occurs as an emergent phenomenon only when individual building blocks bind together in a way that we control by laser light. Using experiments and simulations of two species of immotile microspheres, we exemplify this route by creating active molecules featuring a complex array of behaviors, becoming migrators, spinners, and rotators. The possibility to control the dynamics of active self-assembly via light-controllable nonreciprocal interactions will inspire new approaches to understand living matter and to design active materials.
