English

Interdependent transport via percolation backbones in spatial networks

Physics and Society 2021-02-03 v1

Abstract

The functionality of nodes in a network is often described by the structural feature of belonging to the giant component. However, when dealing with problems like transport, a more appropriate functionality criterion is for a node to belong to the network's backbone, where the flow of information and of other physical quantities (such as current) occurs. Here we study percolation in a model of interdependent resistor networks and show the effect of spatiality on their coupled functioning. We do this on a realistic model of spatial networks, featuring a Poisson distribution of link-lengths. We find that interdependent resistor networks are significantly more vulnerable than their percolation-based counterparts, featuring first-order phase transitions at link-lengths where the mutual giant component still emerges continuously. We explain this apparent contradiction by tracing the origin of the increased vulnerability of interdependent transport to the crucial role played by the dandling ends. Moreover, we interpret these differences by considering an heterogeneous kk-core percolation process which enables to define a one-parameter family of functionality criteria whose constraints become more and more stringent. Our results highlight the importance that different definitions of nodes functionality have on the collective properties of coupled processes, and provide better understanding of the problem of interdependent transport in many real-world networks.

Keywords

Cite

@article{arxiv.2009.02117,
  title  = {Interdependent transport via percolation backbones in spatial networks},
  author = {Bnaya Gross and Ivan Bonamassa and Shlomo Havlin},
  journal= {arXiv preprint arXiv:2009.02117},
  year   = {2021}
}

Comments

7 pages, 6 figures

R2 v1 2026-06-23T18:18:53.355Z