Schelling segregation in an open city: a kinetically constrained Blume-Emery-Griffiths spin-1 system

TL;DR

This paper presents a novel extension of Schelling's segregation model incorporating an external agent reservoir and kinetic constraints, linking it to the Blume-Emery-Griffiths spin-1 model, revealing new segregation phases and interface behaviors.

Contribution

It introduces a dynamic, reservoir-based Schelling model connected to the BEG spin-1 system, exploring new segregation phases and interface phenomena.

Findings

Identifies new segregation phases with distinct interface characteristics.

Analytically and numerically determines the conditions for interface existence.

Shows how agent isolation leads to different segregation patterns.

Abstract

In the 70's Schelling introduced a multi-agent model to describe the segregation dynamics that may occur with individuals having only weak preferences for 'similar' neighbors. Recently variants of this model have been discussed, in particular, with emphasis on the links with statistical physics models. Whereas these models consider a fixed number of agents moving on a lattice, here we present a version allowing for exchanges with an external reservoir of agents. The density of agents is controlled by a parameter which can be viewed as measuring the attractiveness of the city-lattice. This model is directly related to the zero-temperature dynamics of the Blume-Emery-Griffiths (BEG) spin-1 model, with kinetic constraints. With a varying vacancy density, the dynamics with agents making deterministic decisions leads to a new variety of "phases" whose main features are the characteristics of the interfaces between clusters of agents of different types. The domains of existence of each type of interface are obtained analytically as well as numerically. These interfaces may completely isolate the agents leading to another type of segregation as compared to what is observed in the original Schelling model, and we discuss its possible socio-economic correlates.