Flocking in $d=2$ is a genuine non-equilibrium phenomenon for which irreversibility is an essential ingredient. We study a class of minimal flocking models whose only source of irreversibility is self-propulsion and use the entropy production rate (EPR) to quantify the departure from equilibrium across their phase diagrams. The EPR is maximal in the vicinity of the order-disorder transition, where reshuffling of the interaction network is fast. We show that signatures of irreversibility come in the form of asymmetries in the steady state distribution of the flock's microstates. They occur as consequences of the time reversal symmetry breaking in the considered self-propelled systems, independently of the interaction details. In the case of ...
We investigate the effect of kinetic constraints on classical many-body chaos in a translationally-i...
We characterize a system of hard spheres with a simple collision rule that breaks time reversal symm...
Inspired by groups of animals and robots, we study the collective dynamics of large numbers of activ...
Funder: ATTRACT Investigator Grant, Luxembourg National Research Fund Oppenheimer Research Fellowshi...
International audienceWe show that the flocking transition in the Vicsek model is best understood as...
Non-reciprocal interactions are present in many systems out of equilibrium. The rate of entropy prod...
The Vicsek model encompasses the paradigm of active dry matter. Motivated by collective behavior of ...
Time-reversal symmetry breaking and entropy production are universal features of nonequilibrium phen...
We show that arbitrarily large polar flocks are susceptible to the presence of a single small obstac...
Collective biological systems display power laws for macroscopic quantities and are fertile probing ...
We review the past decade's theoretical and experimental studies of flocking: the collective, cohere...
We show that incompressible polar active fluids can exhibit an ordered, coherently moving phase even...
Acknowledgements: MEC thanks Fyl Pincus for inspirational discussions on soft matter physics spannin...
Non-motile active matter exhibits a wide range of non-equilibrium collective phenomena yet examples ...
International audienceWe study in detail the hydrodynamic theories describing the transition to coll...
We investigate the effect of kinetic constraints on classical many-body chaos in a translationally-i...
We characterize a system of hard spheres with a simple collision rule that breaks time reversal symm...
Inspired by groups of animals and robots, we study the collective dynamics of large numbers of activ...
Funder: ATTRACT Investigator Grant, Luxembourg National Research Fund Oppenheimer Research Fellowshi...
International audienceWe show that the flocking transition in the Vicsek model is best understood as...
Non-reciprocal interactions are present in many systems out of equilibrium. The rate of entropy prod...
The Vicsek model encompasses the paradigm of active dry matter. Motivated by collective behavior of ...
Time-reversal symmetry breaking and entropy production are universal features of nonequilibrium phen...
We show that arbitrarily large polar flocks are susceptible to the presence of a single small obstac...
Collective biological systems display power laws for macroscopic quantities and are fertile probing ...
We review the past decade's theoretical and experimental studies of flocking: the collective, cohere...
We show that incompressible polar active fluids can exhibit an ordered, coherently moving phase even...
Acknowledgements: MEC thanks Fyl Pincus for inspirational discussions on soft matter physics spannin...
Non-motile active matter exhibits a wide range of non-equilibrium collective phenomena yet examples ...
International audienceWe study in detail the hydrodynamic theories describing the transition to coll...
We investigate the effect of kinetic constraints on classical many-body chaos in a translationally-i...
We characterize a system of hard spheres with a simple collision rule that breaks time reversal symm...
Inspired by groups of animals and robots, we study the collective dynamics of large numbers of activ...