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Autori principali: Wagner, Timo, Himpel, Michael, Ihle, Thomas, Boltz, Horst-Holger
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.16185
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author Wagner, Timo
Himpel, Michael
Ihle, Thomas
Boltz, Horst-Holger
author_facet Wagner, Timo
Himpel, Michael
Ihle, Thomas
Boltz, Horst-Holger
contents Active matter systems characterized by the interplay of chirality and self-alignment offer a rich landscape for the emergence of non-equilibrium collective behaviors and the development of autonomous materials. We present a versatile experimental platform for studying these dynamics using augmented commercial bristlebots, where custom-designed housings and elastic couplings induce a self-aligning torque and a stable chiral drift. By mapping experimental trajectories to a Langevin-type model, we characterize the single-particle dynamics. In circular geometries, we show that the stability of edge currents is governed by the interaction between intrinsic particle chirality and handedness of the edge current. Furthermore, we demonstrate that transport can be geometrically rectified using a nautilus-shaped obstacle, which acts as a doubly chirality-sensitive ratchet. Finally, we explore the collective dynamics of rigidly linked assemblies, observing spontaneous mode-switching between translational and rotational states in triangular active solids. Our results provide a robust framework for the passive control of active gases and illustrate how geometric constraints can be used to program complex transport properties in synthetic active systems.
format Preprint
id arxiv_https___arxiv_org_abs_2604_16185
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Environmental Control of Self-Aligning Chiral Bristlebots
Wagner, Timo
Himpel, Michael
Ihle, Thomas
Boltz, Horst-Holger
Soft Condensed Matter
Statistical Mechanics
Active matter systems characterized by the interplay of chirality and self-alignment offer a rich landscape for the emergence of non-equilibrium collective behaviors and the development of autonomous materials. We present a versatile experimental platform for studying these dynamics using augmented commercial bristlebots, where custom-designed housings and elastic couplings induce a self-aligning torque and a stable chiral drift. By mapping experimental trajectories to a Langevin-type model, we characterize the single-particle dynamics. In circular geometries, we show that the stability of edge currents is governed by the interaction between intrinsic particle chirality and handedness of the edge current. Furthermore, we demonstrate that transport can be geometrically rectified using a nautilus-shaped obstacle, which acts as a doubly chirality-sensitive ratchet. Finally, we explore the collective dynamics of rigidly linked assemblies, observing spontaneous mode-switching between translational and rotational states in triangular active solids. Our results provide a robust framework for the passive control of active gases and illustrate how geometric constraints can be used to program complex transport properties in synthetic active systems.
title Environmental Control of Self-Aligning Chiral Bristlebots
topic Soft Condensed Matter
Statistical Mechanics
url https://arxiv.org/abs/2604.16185