Trading interactions for topology in scale-free networks

C V Giuraniuc; J P L Hatchett; J O Indekeu; M Leone; I P Castillo; B Van Schaeybroeck; C Vanderzande

doi:10.1103/PhysRevLett.95.098701

Trading interactions for topology in scale-free networks

C V Giuraniuc, J P L Hatchett, J O Indekeu, M Leone, I P Castillo, B Van Schaeybroeck, C Vanderzande

Mathematics

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

43 Citations (Scopus)

Abstract

Scale-free networks with topology-dependent interactions are studied. It is shown that the universality classes of critical behavior, which conventionally depend only on topology, can also be explored by tuning the interactions. A mapping, gamma(')=(gamma-mu)/(1-mu), describes how a shift of the standard exponent gamma of the degree distribution P(q) can absorb the effect of degree-dependent pair interactions J(ij)proportional to(q(i)q(j))(-mu). The replica technique, cavity method, and Monte Carlo simulation support the physical picture suggested by Landau theory for the critical exponents and by the Bethe-Peierls approximation for the critical temperature. The equivalence of topology and interaction holds for equilibrium and nonequilibrium systems, and is illustrated with interdisciplinary applications

Original language	English
Article number	098701
Journal	Physical Review Letters
Volume	95
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.95.098701
Publication status	Published - 26 Aug 2005

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title = "Trading interactions for topology in scale-free networks",

abstract = "Scale-free networks with topology-dependent interactions are studied. It is shown that the universality classes of critical behavior, which conventionally depend only on topology, can also be explored by tuning the interactions. A mapping, gamma(')=(gamma-mu)/(1-mu), describes how a shift of the standard exponent gamma of the degree distribution P(q) can absorb the effect of degree-dependent pair interactions J(ij)proportional to(q(i)q(j))(-mu). The replica technique, cavity method, and Monte Carlo simulation support the physical picture suggested by Landau theory for the critical exponents and by the Bethe-Peierls approximation for the critical temperature. The equivalence of topology and interaction holds for equilibrium and nonequilibrium systems, and is illustrated with interdisciplinary applications",

author = "Giuraniuc, {C V} and Hatchett, {J P L} and Indekeu, {J O} and M Leone and Castillo, {I P} and {Van Schaeybroeck}, B and C Vanderzande",

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AU - Giuraniuc, C V

AU - Hatchett, J P L

AU - Indekeu, J O

AU - Leone, M

AU - Castillo, I P

AU - Van Schaeybroeck, B

AU - Vanderzande, C

PY - 2005/8/26

Y1 - 2005/8/26

N2 - Scale-free networks with topology-dependent interactions are studied. It is shown that the universality classes of critical behavior, which conventionally depend only on topology, can also be explored by tuning the interactions. A mapping, gamma(')=(gamma-mu)/(1-mu), describes how a shift of the standard exponent gamma of the degree distribution P(q) can absorb the effect of degree-dependent pair interactions J(ij)proportional to(q(i)q(j))(-mu). The replica technique, cavity method, and Monte Carlo simulation support the physical picture suggested by Landau theory for the critical exponents and by the Bethe-Peierls approximation for the critical temperature. The equivalence of topology and interaction holds for equilibrium and nonequilibrium systems, and is illustrated with interdisciplinary applications

AB - Scale-free networks with topology-dependent interactions are studied. It is shown that the universality classes of critical behavior, which conventionally depend only on topology, can also be explored by tuning the interactions. A mapping, gamma(')=(gamma-mu)/(1-mu), describes how a shift of the standard exponent gamma of the degree distribution P(q) can absorb the effect of degree-dependent pair interactions J(ij)proportional to(q(i)q(j))(-mu). The replica technique, cavity method, and Monte Carlo simulation support the physical picture suggested by Landau theory for the critical exponents and by the Bethe-Peierls approximation for the critical temperature. The equivalence of topology and interaction holds for equilibrium and nonequilibrium systems, and is illustrated with interdisciplinary applications

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DO - 10.1103/PhysRevLett.95.098701

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SN - 1079-7114

VL - 95

JO - Physical Review Letters

JF - Physical Review Letters

IS - 9

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ER -

Trading interactions for topology in scale-free networks

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