Possible origin for the similar phase transitions in k-core and interdependent networks

Abstract

The models of k-core percolation and interdependent networks (IN) have been extensively studied in their respective fields. A recent study has revealed that they share several common critical exponents. However, several newly discovered exponents in IN have not been explored in k-core percolation, and the origin of the similarity still remains unclear. Here, we investigate k-core percolation in random networks. We find that for k-core percolation,the fractality of the giant component fluctuations is manifested by a fractal fluctuation dimension, df = 3/4, within a correlation size N' that scales as N' (p-pc)-, with = 2, same as found in IN. Indeed, here, d· ' and df d'f/d, where ' and d'f are respectively the same as the correlation length exponent and the fractal fluctuation dimension observed in d-dimensional IN spatial networks. These two new exponents found here for k-core percolation demonstrate the same scaling behaviors as found for IN with the same critical exponents, reinforcing the similarity between the two models. Furthermore, we suggest that these two models are similar since both have two types of interactions: short-range (SR) connectivity and long-range (LR) influences. In IN the LR are the influences of dependency links while in k-core we find here that for k=1 and k=2 the influences are short range while for k≥3 the influence is long range. In addition, analytical arguments for a universal hyper-scaling relation for the fractal fluctuation dimension of the k-core giant component and for IN as well as for any mixed-order transition are established.Our analysis enhances the comprehension of k-core percolation and supports the generalization of the concept of fractal fluctuations in mixed-order phase transitions.