Von Neumann's expanding model on random graphs

A De Martino; C Martelli; R Monasson; I P Castillo

Von Neumann's expanding model on random graphs

A De Martino, C Martelli, R Monasson, I P Castillo

Mathematics

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

16 Citations (Scopus)

Abstract

Within the framework of Von Neumann's expanding model, we study the maximum growth rate rho* achievable by an autocatalytic reaction network in which reactions involve a finite (fixed or fluctuating) number D of reagents. rho* is calculated numerically using a variant of the Minover algorithm, and analytically via the cavity method for disordered systems. As the ratio between the number of reactions and that of reagents increases the system passes from a contracting (rho* <1) to an expanding regime (rho* > 1). These results extend the scenario derived in the fully connected model (D -> infinity), with the important difference that, generically, larger growth rates are achievable in the expanding phase for finite D and in more diluted networks. Moreover, the range of attainable values of rho* shrinks as the connectivity increases

Original language	English
Article number	P05012
Journal	Journal of Statistical Mechanics: Theory and Experiment
Issue number	MAY
Publication status	Published - 2007

Cite this

@article{d2e430acb8d94c2d97231b30fa2d01e2,

title = "Von Neumann's expanding model on random graphs",

abstract = "Within the framework of Von Neumann's expanding model, we study the maximum growth rate rho* achievable by an autocatalytic reaction network in which reactions involve a finite (fixed or fluctuating) number D of reagents. rho* is calculated numerically using a variant of the Minover algorithm, and analytically via the cavity method for disordered systems. As the ratio between the number of reactions and that of reagents increases the system passes from a contracting (rho* <1) to an expanding regime (rho* > 1). These results extend the scenario derived in the fully connected model (D -> infinity), with the important difference that, generically, larger growth rates are achievable in the expanding phase for finite D and in more diluted networks. Moreover, the range of attainable values of rho* shrinks as the connectivity increases",

author = "{De Martino}, A and C Martelli and R Monasson and Castillo, {I P}",

year = "2007",

language = "English",

journal = "Journal of Statistical Mechanics: Theory and Experiment",

publisher = "IOP Publishing Ltd.",

number = "MAY",

}

TY - JOUR

T1 - Von Neumann's expanding model on random graphs

AU - De Martino, A

AU - Martelli, C

AU - Monasson, R

AU - Castillo, I P

PY - 2007

Y1 - 2007

N2 - Within the framework of Von Neumann's expanding model, we study the maximum growth rate rho* achievable by an autocatalytic reaction network in which reactions involve a finite (fixed or fluctuating) number D of reagents. rho* is calculated numerically using a variant of the Minover algorithm, and analytically via the cavity method for disordered systems. As the ratio between the number of reactions and that of reagents increases the system passes from a contracting (rho* <1) to an expanding regime (rho* > 1). These results extend the scenario derived in the fully connected model (D -> infinity), with the important difference that, generically, larger growth rates are achievable in the expanding phase for finite D and in more diluted networks. Moreover, the range of attainable values of rho* shrinks as the connectivity increases

AB - Within the framework of Von Neumann's expanding model, we study the maximum growth rate rho* achievable by an autocatalytic reaction network in which reactions involve a finite (fixed or fluctuating) number D of reagents. rho* is calculated numerically using a variant of the Minover algorithm, and analytically via the cavity method for disordered systems. As the ratio between the number of reactions and that of reagents increases the system passes from a contracting (rho* <1) to an expanding regime (rho* > 1). These results extend the scenario derived in the fully connected model (D -> infinity), with the important difference that, generically, larger growth rates are achievable in the expanding phase for finite D and in more diluted networks. Moreover, the range of attainable values of rho* shrinks as the connectivity increases

M3 - Article

JO - Journal of Statistical Mechanics: Theory and Experiment

JF - Journal of Statistical Mechanics: Theory and Experiment

IS - MAY

M1 - P05012

ER -

Von Neumann's expanding model on random graphs

Abstract

Fingerprint

Cite this