Critical Stretching of Mean-Field Regimes in Spatial Networks

Ivan Bonamassa; Bnaya Gross; Michael M. Danziger; Shlomo Havlin

doi:10.1103/PhysRevLett.123.088301

Critical Stretching of Mean-Field Regimes in Spatial Networks

Ivan Bonamassa, Bnaya Gross, Michael M. Danziger, Shlomo Havlin

Research output: Contribution to journal › Article › peer-review

Abstract (may include machine translation)

We study a spatial network model with exponentially distributed link lengths on an underlying grid of points, undergoing a structural crossover from a random, Erdos-Rényi graph, to a d-dimensional lattice at the characteristic interaction range ζ. We find that, whilst far from the percolation threshold the random part of the giant component scales linearly with ζ, close to criticality it extends in space until the universal length scale ζ6/(6-d), for d<6, before crossing over to the spatial one. We demonstrate the universal behavior of the spatiotemporal scales characterizing this critical stretching phenomenon of mean-field regimes in percolation and in dynamical processes on d=2 networks, and we discuss its general implications to real-world phenomena, such as neural activation, traffic flows or epidemic spreading.

Original language	English
Article number	088301
Journal	Physical Review Letters
Volume	123
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevLett.123.088301
State	Published - 22 Aug 2019
Externally published	Yes

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title = "Critical Stretching of Mean-Field Regimes in Spatial Networks",

abstract = "We study a spatial network model with exponentially distributed link lengths on an underlying grid of points, undergoing a structural crossover from a random, Erdos-R{\'e}nyi graph, to a d-dimensional lattice at the characteristic interaction range ζ. We find that, whilst far from the percolation threshold the random part of the giant component scales linearly with ζ, close to criticality it extends in space until the universal length scale ζ6/(6-d), for d<6, before crossing over to the spatial one. We demonstrate the universal behavior of the spatiotemporal scales characterizing this critical stretching phenomenon of mean-field regimes in percolation and in dynamical processes on d=2 networks, and we discuss its general implications to real-world phenomena, such as neural activation, traffic flows or epidemic spreading.",

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AB - We study a spatial network model with exponentially distributed link lengths on an underlying grid of points, undergoing a structural crossover from a random, Erdos-Rényi graph, to a d-dimensional lattice at the characteristic interaction range ζ. We find that, whilst far from the percolation threshold the random part of the giant component scales linearly with ζ, close to criticality it extends in space until the universal length scale ζ6/(6-d), for d<6, before crossing over to the spatial one. We demonstrate the universal behavior of the spatiotemporal scales characterizing this critical stretching phenomenon of mean-field regimes in percolation and in dynamical processes on d=2 networks, and we discuss its general implications to real-world phenomena, such as neural activation, traffic flows or epidemic spreading.

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Critical Stretching of Mean-Field Regimes in Spatial Networks

Abstract (may include machine translation)

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