English

Scale-free networks are rare

Physics and Society 2019-03-19 v1 Social and Information Networks Data Analysis, Statistics and Probability Molecular Networks Applications

Abstract

A central claim in modern network science is that real-world networks are typically "scale free," meaning that the fraction of nodes with degree kk follows a power law, decaying like kαk^{-\alpha}, often with 2<α<32 < \alpha < 3. However, empirical evidence for this belief derives from a relatively small number of real-world networks. We test the universality of scale-free structure by applying state-of-the-art statistical tools to a large corpus of nearly 1000 network data sets drawn from social, biological, technological, and informational sources. We fit the power-law model to each degree distribution, test its statistical plausibility, and compare it via a likelihood ratio test to alternative, non-scale-free models, e.g., the log-normal. Across domains, we find that scale-free networks are rare, with only 4% exhibiting the strongest-possible evidence of scale-free structure and 52% exhibiting the weakest-possible evidence. Furthermore, evidence of scale-free structure is not uniformly distributed across sources: social networks are at best weakly scale free, while a handful of technological and biological networks can be called strongly scale free. These results undermine the universality of scale-free networks and reveal that real-world networks exhibit a rich structural diversity that will likely require new ideas and mechanisms to explain.

Keywords

Cite

@article{arxiv.1801.03400,
  title  = {Scale-free networks are rare},
  author = {Anna D. Broido and Aaron Clauset},
  journal= {arXiv preprint arXiv:1801.03400},
  year   = {2019}
}

Comments

14 pages, 9 figures, 2 tables, 5 appendices

R2 v1 2026-06-22T23:41:41.898Z