English

Phase transition in evolving networks that combine preferential attachment and random node deletion

Statistical Mechanics 2025-01-13 v1 Adaptation and Self-Organizing Systems Physics and Society

Abstract

Analytical results are presented for the structure of networks that evolve via a preferential-attachment-random-deletion (PARD) model in the regime of overall network growth and in the regime of overall contraction. The phase transition between the two regimes is studied. At each time step a node addition and preferential attachment step takes place with probability PaddP_{\rm add}, and a random node deletion step takes place with probability Pdel=1PaddP_{\rm del} = 1 - P_{\rm add}. The balance between growth and contraction is captured by the parameter η=PaddPdel\eta = P_{\rm add} - P_{\rm del}, which in the regime of overall network growth satisfies 0<η10 < \eta \le 1 and in the regime of overall network contraction 1η<0-1 \le \eta < 0. Using the master equation and computer simulations we show that for 1<η<0-1 < \eta < 0 the time-dependent degree distribution Pt(k)P_t(k) converges towards a stationary form Pst(k)P_{\rm st}(k) which exhibits an exponential tail. This is in contrast with the power-law tail of the stationary degree distribution obtained for 0<η10 < \eta \le 1. Thus, the PARD model has a phase transition at η=0\eta=0, which separates between two structurally distinct phases. At the transition, for η=0\eta=0, the degree distribution exhibits a stretched exponential tail. While the stationary degree distribution in the phase of overall growth represents an asymptotic state, in the phase of overall contraction Pst(k)P_{\rm st}(k) represents an intermediate asymptotic state of a finite life span, which disappears when the network vanishes.

Keywords

Cite

@article{arxiv.2412.14549,
  title  = {Phase transition in evolving networks that combine preferential attachment and random node deletion},
  author = {Barak Budnick and Ofer Biham and Eytan Katzav},
  journal= {arXiv preprint arXiv:2412.14549},
  year   = {2025}
}

Comments

32 pages, 6 figures. arXiv admin note: text overlap with arXiv:2209.10027

R2 v1 2026-06-28T20:41:41.631Z