Related papers: Emergence of disconnected clusters in heterogeneous complex systems

Emergence of disconnected clusters in heterogeneous complex systems

URL: http://arxiv.org/abs/2012.00447v2
Date: Wed, 2 Dec 2020 12:45:20 GMT
Title: Emergence of disconnected clusters in heterogeneous complex systems
Authors: Istv\'an A. Kov\'acs and R\'obert Juh\'asz
Abstract summary: We show that highly correlated sites in complex systems can be inherently disconnected. This finding indicates a counter-intuitive organization of dynamical correlations, where similarity decouples from physical connectivity.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Percolation theory dictates an intuitive picture depicting correlated regions in complex systems as densely connected clusters. While this picture might be adequate at small scales and apart from criticality, we show that highly correlated sites in complex systems can be inherently disconnected. This finding indicates a counter-intuitive organization of dynamical correlations, where functional similarity decouples from physical connectivity. We illustrate the phenomena on the example of the Disordered Contact Process (DCP) of infection spreading in heterogeneous systems. We apply numerical simulations and an asymptotically exact renormalization group technique (SDRG) in 1, 2 and 3 dimensional systems as well as in two-dimensional lattices with long-ranged interactions. We conclude that the critical dynamics is well captured by mostly one, highly correlated, but spatially disconnected cluster. Our findings indicate that at criticality the relevant, simultaneously infected sites typically do not directly interact with each other. Due to the similarity of the SDRG equations, our results hold also for the critical behavior of the disordered quantum Ising model, leading to quantum correlated, yet spatially disconnected, magnetic domains.

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