Magnetic Microswimmers Exhibit Bose-Einstein-like Condensation

Meng, Fanlong; Matsunaga, Daiki; Mahault, Benoit; Golestanian, Ramin

doi:10.1103/PhysRevLett.126.078001

Item

ITEM ACTIONSEXPORT

Add to Basket

Local TagsRelease HistoryDetailsSummary

Released

Journal Article

Magnetic Microswimmers Exhibit Bose-Einstein-like Condensation

MPS-Authors

/persons/resource/persons227777

Meng, Fanlong
Department of Living Matter Physics, Max Planck Institute for Dynamics and Self-Organization, Max Planck Society;

/persons/resource/persons243224

Mahault, Benoit
Department of Living Matter Physics, Max Planck Institute for Dynamics and Self-Organization, Max Planck Society;

/persons/resource/persons219873

Golestanian, Ramin
Department of Living Matter Physics, Max Planck Institute for Dynamics and Self-Organization, Max Planck Society;

External Resource

No external resources are shared

Fulltext (restricted access)

There are currently no full texts shared for your IP range.

Fulltext (public)

There are no public fulltexts stored in PuRe

Supplementary Material (public)

There is no public supplementary material available

Citation

Meng, F., Matsunaga, D., Mahault, B., & Golestanian, R. (2021). Magnetic Microswimmers Exhibit Bose-Einstein-like Condensation. Physical Review Letters, 126: 078001. doi:10.1103/PhysRevLett.126.078001.

Cite as: https://hdl.handle.net/21.11116/0000-0008-1186-D

Abstract

We study an active matter system comprised of magnetic microswimmers confined in a microfluidic channel and show that it exhibits a new type of self-organized behavior. Combining analytical techniques and Brownian dynamics simulations, we demonstrate how the interplay of nonequilibrium activity, external driving, and magnetic interactions leads to the condensation of swimmers at the center of the channel via a nonequilibrium phase transition that is formally akin to Bose-Einstein condensation. We find that the effective dynamics of the microswimmers can be mapped onto a diffusivity-edge problem, and use the mapping to build a generalized thermodynamic framework, which is verified by a parameter-free comparison with our simulations. Our work reveals how driven active matter has the potential to generate exotic classical nonequilibrium phases of matter with traits that are analogous to those observed in quantum systems.