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Main Authors: Woo, Chul-Ung, Rieger, Heiko, Noh, Jae Dong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.18756
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author Woo, Chul-Ung
Rieger, Heiko
Noh, Jae Dong
author_facet Woo, Chul-Ung
Rieger, Heiko
Noh, Jae Dong
contents We investigate collective behavior in a $Q$-species Vicsek model with a nonreciprocal velocity alignment interaction. This system is characterized by a constant phase shift $α$ in the inter-species velocity alignment rule. While the phase shift renders the interaction nonreciprocal, the system is globally invariant under any permutations of particle species, possessing Potts symmetry. The combination of Potts symmetry and nonreciprocity gives rise to a rich phase diagram. The nonreciprocal phase shift generates either counter-clockwise or clockwise chirality. Potts symmetry can be broken spontaneously. Consequently, the system exhibits four distinct phases: A species-mixed chiral phase where particles perform counter-clockwise chiral motion with quasi-long-range order, a species separation phase where Potts symmetry is broken and species-separated particles form vortex cells with clockwise chirality, a coexistence phase, and a disordered phase. We derive a Boltzmann equation and a hydrodynamic equation describing the system in the continuum limit, and present analytic arguments for the emergence of chirality and species separation.
format Preprint
id arxiv_https___arxiv_org_abs_2512_18756
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Collective behavior in the nonreciprocal multi-species Vicsek model
Woo, Chul-Ung
Rieger, Heiko
Noh, Jae Dong
Statistical Mechanics
We investigate collective behavior in a $Q$-species Vicsek model with a nonreciprocal velocity alignment interaction. This system is characterized by a constant phase shift $α$ in the inter-species velocity alignment rule. While the phase shift renders the interaction nonreciprocal, the system is globally invariant under any permutations of particle species, possessing Potts symmetry. The combination of Potts symmetry and nonreciprocity gives rise to a rich phase diagram. The nonreciprocal phase shift generates either counter-clockwise or clockwise chirality. Potts symmetry can be broken spontaneously. Consequently, the system exhibits four distinct phases: A species-mixed chiral phase where particles perform counter-clockwise chiral motion with quasi-long-range order, a species separation phase where Potts symmetry is broken and species-separated particles form vortex cells with clockwise chirality, a coexistence phase, and a disordered phase. We derive a Boltzmann equation and a hydrodynamic equation describing the system in the continuum limit, and present analytic arguments for the emergence of chirality and species separation.
title Collective behavior in the nonreciprocal multi-species Vicsek model
topic Statistical Mechanics
url https://arxiv.org/abs/2512.18756