First order phase transition in a self-propelled particles model with variable angular range of interaction

TL;DR

This study uses Monte Carlo simulations to explore how varying the angular range of interaction in a self-propelled particles model causes a first order phase transition from ordered to disordered motion, highlighting the importance of interaction directionality.

Contribution

It introduces a modified Vicsek model with variable interaction angular range and demonstrates its impact on phase transition nature and collective motion.

Findings

Ordered motion persists at small view-angles.

A first order phase transition occurs at a critical view-angle.

Reducing view-angle can enhance system order.

Abstract

We have carried out a Monte Carlo simulation of a modified version of Vicsek model for the motion of self-propelled particles in two dimensions. In this model the neighborhood of interaction of a particle is a sector of the circle with the particle at the center (rather than the whole circle as in the original Vicsek model). The sector is centered along the direction of the velocity of the particle, and the half-opening angle of this sector is called the `view-angle'. We vary the view-angle over its entire range and study the change in the nature of the collective motion of the particles. We find that ordered collective motion persists down to remarkably small view-angles. And at a certain critical view-angle the collective motion of the system undergoes a first order phase transition to a disordered state. We also find that the reduction in the view-angle can in fact increase the order in the system significantly. We show that the directionality of the interaction, and not only the radial range of the interaction, plays an important role in the determination of the nature of the above phase transition.