Limit distributions in random resistor networks

Rafael F. Angulo; Ernesto Medina

doi:10.1016/0378-4371(92)90559-9

Limit distributions in random resistor networks

Rafael F. Angulo^*
, Ernesto Medina

^*Corresponding author for this work

Petróleos de Venezuela, S.A.

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

1 Scopus citations

Abstract

The question of attraction to stable limit distributions in random resistor networks (RRNs) is explored numerically. Transport in networks with power law distributions of conductances of the form P(g) = |μ|g^μ-1 are considered. Distributions of equivalent conductances are estimated on hierarchical lattices as a function of size L and the parameter μ. We find that only lattices at the percolation threshold can support transport in a Levy-like basin. For networks above the percolation threshold, convergence to a Gaussian basin is always the case, and a disorder length ξ_D is identified, beyond which the system is effectively homogeneous. This length scale diverges, when the microscopic distribution of conductors is exponentially wide (μ→0), as ξ_D∼|μ|^-1.6-0.1.

Original language	English
Pages (from-to)	410-414
Number of pages	5
Journal	Physica A: Statistical Mechanics and its Applications
Volume	191
Issue number	1-4
DOIs	https://doi.org/10.1016/0378-4371(92)90559-9
State	Published - 15 Dec 1992
Externally published	Yes

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title = "Limit distributions in random resistor networks",

abstract = "The question of attraction to stable limit distributions in random resistor networks (RRNs) is explored numerically. Transport in networks with power law distributions of conductances of the form P(g) = |μ|gμ-1 are considered. Distributions of equivalent conductances are estimated on hierarchical lattices as a function of size L and the parameter μ. We find that only lattices at the percolation threshold can support transport in a Levy-like basin. For networks above the percolation threshold, convergence to a Gaussian basin is always the case, and a disorder length ξD is identified, beyond which the system is effectively homogeneous. This length scale diverges, when the microscopic distribution of conductors is exponentially wide (μ→0), as ξD∼|μ|-1.6-0.1.",

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AU - Medina, Ernesto

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N2 - The question of attraction to stable limit distributions in random resistor networks (RRNs) is explored numerically. Transport in networks with power law distributions of conductances of the form P(g) = |μ|gμ-1 are considered. Distributions of equivalent conductances are estimated on hierarchical lattices as a function of size L and the parameter μ. We find that only lattices at the percolation threshold can support transport in a Levy-like basin. For networks above the percolation threshold, convergence to a Gaussian basin is always the case, and a disorder length ξD is identified, beyond which the system is effectively homogeneous. This length scale diverges, when the microscopic distribution of conductors is exponentially wide (μ→0), as ξD∼|μ|-1.6-0.1.

AB - The question of attraction to stable limit distributions in random resistor networks (RRNs) is explored numerically. Transport in networks with power law distributions of conductances of the form P(g) = |μ|gμ-1 are considered. Distributions of equivalent conductances are estimated on hierarchical lattices as a function of size L and the parameter μ. We find that only lattices at the percolation threshold can support transport in a Levy-like basin. For networks above the percolation threshold, convergence to a Gaussian basin is always the case, and a disorder length ξD is identified, beyond which the system is effectively homogeneous. This length scale diverges, when the microscopic distribution of conductors is exponentially wide (μ→0), as ξD∼|μ|-1.6-0.1.

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JO - Physica A: Statistical Mechanics and its Applications

JF - Physica A: Statistical Mechanics and its Applications

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Limit distributions in random resistor networks

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