Active Matter in Space

Overview

Journal NPJ Microgravity

Publisher Springer Nature

Date 2022 Nov 26

PMID 36434006

Authors

Giorgio Volpe

Clemens Bechinger

Frank Cichos

Ramin Golestanian

Hartmut Lowen

Matthias Sperl

Giovanni Volpe

Affiliations

Soon will be listed here.

Abstract

In the last 20 years, active matter has been a highly dynamic field of research, bridging fundamental aspects of non-equilibrium thermodynamics with applications to biology, robotics, and nano-medicine. Active matter systems are composed of units that can harvest and harness energy and information from their environment to generate complex collective behaviours and forms of self-organisation. On Earth, gravity-driven phenomena (such as sedimentation and convection) often dominate or conceal the emergence of these dynamics, especially for soft active matter systems where typical interactions are of the order of the thermal energy. In this review, we explore the ongoing and future efforts to study active matter in space, where low-gravity and microgravity conditions can lift some of these limitations. We envision that these studies will help unify our understanding of active matter systems and, more generally, of far-from-equilibrium physics both on Earth and in space. Furthermore, they will also provide guidance on how to use, process and manufacture active materials for space exploration and colonisation.

Citing Articles

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Te Vrugt M, Wittkowski R Eur Phys J E Soft Matter. 2025; 48(3):12.

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