Topologically controlled synthesis of active colloidal bipeds

Elschner, Jonas; Farrokhzad, Farzaneh; Kuświk, Piotr; Urbaniak, Maciej; Stobiecki, Feliks; Akhundzada, Sapida; Ehresmann, Arno; de las Heras, Daniel; Fischer, Thomas M.

Topologically controlled synthesis of active colloidal bipeds

Jonas Elschner, Farzaneh Farrokhzad, Piotr Kuświk, Maciej Urbaniak, Feliks Stobiecki, Sapida Akhundzada, Arno Ehresmann, Daniel de las Heras and Thomas M. Fischer ()
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Jonas Elschner: Universität Bayreuth
Farzaneh Farrokhzad: Universität Bayreuth
Piotr Kuświk: Polish Academy of Sciences
Maciej Urbaniak: Polish Academy of Sciences
Feliks Stobiecki: Polish Academy of Sciences
Sapida Akhundzada: Universität Kassel
Arno Ehresmann: Universität Kassel
Daniel de las Heras: Universität Bayreuth
Thomas M. Fischer: Universität Bayreuth

Nature Communications, 2024, vol. 15, issue 1, 1-12

Abstract: Abstract Topological growth control allows to produce a narrow distribution of outgrown colloidal rods with defined and adjustable length. We use an external magnetic field to assemble paramagnetic colloidal spheres into colloidal rods of a chosen length. The rods reside above a metamorphic hexagonal magnetic pattern. The periodic repetition of specific loops of the orientation of an applied external field renders paramagnetic colloidal particles and their assemblies into active bipeds that walk on the pattern. The metamorphic patterns allow the robust and controlled polymerization of single colloids to bipeds of a desired length. The colloids are exposed to this fixed external control loop that causes multiple simultaneous responses: Small bipeds and single colloidal particles interpret the external magnetic loop as an order to walk toward the active zone, where they assemble and polymerize. Outgrown bipeds interpret the same loop as an order to walk away from the active zone. The topological transition occurs solely for the growing biped and nothing is changed in the environment nor in the magnetic control loop. As in many biological systems the decision of a biped that reached its outgrown length to walk away from the reaction site is made internally, not externally.

Date: 2024
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DOI: 10.1038/s41467-024-50023-7

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