Testing the Universality of Self-Organized Criticality in Galactic, Extra-Galactic, and Black-Hole Systems

TL;DR

This study tests whether power law slopes in flux and energy distributions are universal across various astrophysical systems, supporting the idea that self-organized criticality naturally explains these distributions without complex physical models.

Contribution

It provides strong statistical evidence that power law slopes are universal in astrophysical systems, supporting the self-organized criticality theory's predictions.

Findings

Power law slopes are consistent across galactic, extragalactic, and black-hole systems.

Observed slopes match the fractal-diffusive SOC model predictions.

Results support the universality of SOC in astrophysical phenomena.

Abstract

In this study we are testing whether the power law slopes ($\alpha_F$, $\alpha_E$) of fluxes $(F)$, fluences or energies $(E)$ are universal in their size distributions, $N(F) \propto F^{-\alpha_F}$ and $N(E) \propto E^{-\alpha_E}$, in astrophysical observations of galactic, extragalactic, and black-hole systems. This is a test of fundamental importance for self-organized criticality (SOC) systems. The test decides whether (i) power laws are a natural consequence of the scale-freeness and inherent universality of SOC systems, or (ii) if they depend on more complex physical scaling laws. The former criterion allows quantitative predictions of the power law-like size distributions, while the later criterion requires individual physical modeling for each SOC variable and data set. Our statistical test, carried out with 61 published data sets, yields strong support for the former option, which implies that observed power laws can simply be derived from the scale-freeness and do not require specific physical models to understand their statistical distributions. The observations show a mean and standard deviation of $\alpha_F=1.78\pm0.29$ for SOC fluxes, and $\alpha_E=1.66\pm0.22$ for SOC fluences, and thus are consistent with the prediction of the fractal-diffusive SOC model, with $\alpha_F=1.80$ and $\alpha_E=1.67$.