How initial distribution affects symmetry breaking induced by panic in ants: experiment and flee-pheromone model

TL;DR

This study investigates how initial distribution affects symmetry breaking in ant panic escape, revealing a counter-intuitive lack of correlation and introducing a flee-pheromone model to explain early escape behavior.

Contribution

The paper introduces a novel two-stage model of ant panic escaping, explicitly distinguishing the flee stage and providing experimental validation.

Findings

No positive correlation between initial asymmetry and symmetry breaking.

Flee-pheromone model accurately reproduces experimental observations.

Quantitative calibration of flee stage duration.

Abstract

Collective escaping is a ubiquitous phenomenon in animal groups. Symmetry breaking caused by panic escape exhibits a shared feature across species that one exit is used more than the other when agents escaping from a closed space with two symmetrically located exists. Intuitively, one exit will be used more by more individuals close to it, namely there is an asymmetric distribution initially. We used ant groups to investigate how initial distribution of colonies would influence symmetry breaking in collective escaping. Surprisingly, there was no positive correlation between symmetry breaking and the asymmetrically initial distribution, which was quite counter-intuitive. In the experiments, a flee stage was observed and accordingly a flee-pheromone model was introduced to depict this special behavior in the early stage of escaping. Simulation results fitted well with the experiment. Furthermore, the flee stage duration was calibrated quantitatively and the model reproduced the observation demonstrated by our previous work. This paper explicitly distinguished two stages in ant panic escaping for the first time, thus enhancing the understanding in escaping behavior of ant colonies.