Scale-Free Networks beyond Power-Law Degree Distribution

Complex networks across various fields are often considered to be scale free -- a statistical property usually solely characterized by a power-law distribution of the nodes' degree $k$. However, this characterization is incomplete. In real-world networks, the distribution of the degree-degree distance $\eta$, a simple link-based metric of network connectivity similar to $k$, appears to exhibit a stronger power-law distribution than $k$. While offering an alternative characterization of scale-freeness, the discovery of $\eta$ raises a fundamental question: do the power laws of $k$ and $\eta$ represent the same scale-freeness? To address this question, here we investigate the exact asymptotic {relationship} between the distributions of $k$ and $\eta$, proving that every network with a power-law distribution of $k$ also has a power-law distribution of $\eta$, but \emph{not} vice versa. This prompts us to introduce two network models as counterexamples that have a power-law distribution of $\eta$ but not $k$, constructed using the preferential attachment and fitness mechanisms, respectively. Both models show promising accuracy by fitting only one model parameter each when modeling real-world networks. Our findings suggest that $\eta$ is a more suitable indicator of scale-freeness and can provide a deeper understanding of the universality and underlying mechanisms of scale-free networks.