A Universal Scaling Law for the Fractal Energy Dissipation Domain in Self-Organized Criticality Systems

Abstract

Nonlinear dissipative systems in the state of self-organized criticality release energy sporadically in avalanches of all sizes, such as in earthquakes, auroral substorms, solar and stellar flares, soft gamma-ray repeaters, and pulsar glitches. The statistical occurrence frequency distributions of event energies E generally exhibit a powerlaw-like function N(E) E-αE with a powerlaw slope of αE ≈ 1.5. The powerlaw slope αE of energies can be related to the fractal dimension D of the spatial energy dissipation domain by D=3/αE, which predicts a powerlaw slope αE=1.5 for area-rupturing or area-spreading processes with D=2. For solar and stellar flares, 2-D area-spreading dissipation domains are naturally provided in current sheets or separatrix surfaces in a magnetic reconnection region. Thus, this universal scaling law provides a useful new diagnostic on the topology of the spatial energy dissipation domain in geophysical and astrophysical observations.