English

Mapping Sandpiles to Complex Networks

Statistical Mechanics 2025-01-28 v1

Abstract

In this paper, we address a longstanding challenge in self-organized criticality (SOC) systems: establishing a connection between sandpiles and complex networks. Our approach employs a similarity-based transfer function characterized by two parameters, R=(r1,r2)\mathcal{R}=(r_1, r_2). Here, r1r_1 quantifies the similarity of local activities, while r2r_2 governs the filtration process used to convert a weighted network into a binary one. We reveal that the degree centrality distribution of the resulting network follows a generalized Gamma distribution (GGD), which transitions to a power-law distribution under specific conditions. The GGD exponents, estimated numerically, exhibit a dependency on R\mathcal{R}. Notably, while both decreasing r1r_1 and r2r_2 lead to denser networks, r2r_2 plays a more significant role in influencing network density. Furthermore, the Shannon entropy is observed to decrease linearly with increasing r2r_2, whereas its variation with r1r_1 is more gradual. An analytical expression for the Shannon entropy is proposed. To characterize the network structure, we investigate the clustering coefficient (cccc), eigenvalue centrality (ee), closeness centrality (cc), and betweenness centrality (bb). The distributions of cccc, ee, and cc exhibit peaked profiles, while bb displays a power-law distribution over a finite interval of kk. Additionally, we explore correlations between the exponents and identify a specific parameter regime of R\mathcal{R} and kk where the eke-k, ckc-k, and bkb-k correlations become negative.

Keywords

Cite

@article{arxiv.2501.15845,
  title  = {Mapping Sandpiles to Complex Networks},
  author = {Abbas Shoja-Daliklidash and Morteza Nattagh-Najafi and Nasser Sepehri-Javan},
  journal= {arXiv preprint arXiv:2501.15845},
  year   = {2025}
}
R2 v1 2026-06-28T21:19:05.252Z