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Unifying criticality and the neutral theory of neural avalanches
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It is shown that the neutral theory of neural avalanches can be unified with criticality, which requires fine tuning of control parameters, and rule out self-organized criticality.Abstract:
The distribution of collective firing of neurons, known as a neural avalanche, obeys a power law. Three proposed explanations of this emergent scale-free behavior are criticality, neutral theory, and self-organized criticality. We show that the neutral theory of neural avalanches can be unified with criticality, which requires fine tuning of control parameters, and rule out self-organized criticality. We study a model of the brain for which the dynamics are governed by neutral theory. We identify the tuning parameters, which are consistent with experiments, and show that scale-free neural avalanches occur only at the critical point. The scaling hypothesis provides a unified explanation of the power laws which characterize the critical point. The critical exponents characterizing the avalanche distributions and divergence of the response functions are shown to be consistent with the predictions of the scaling hypothesis. We use an universal scaling function for the avalanche profile to find that the firing rate for avalanches of different sizes shows data collapse after appropriate rescaling. Critical slowing-down and algebraic relaxation of avalanches demonstrate that the dynamics are also consistent with the system being at a critical point. We discuss how our results can motivate future empirical studies of criticality in the brain.read more
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Journal Article
Effective ergodicity breaking phase transition in a driven-dissipative system
Abstract: We show that the Olami-Feder-Christensen model exhibits an effective ergodicity breaking transition as the noise is varied. Above the critical noise, the system is effectively ergodic because the time-averaged stress on each site converges to the global spatial average. In contrast, below the critical noise, the stress on individual sites becomes trapped in different limit cycles, and the system is not ergodic. To characterize this transition, we use ideas from the study of dynamical systems and compute recurrence plots and the recurrence rate. The order parameter is identified as the recurrence rate averaged over all sites and exhibits a jump at the critical noise. We also use ideas from percolation theory and analyze the clusters of failed sites to find numerical evidence that the transition, when approached from above, can be characterized by exponents that are consistent with hyperscaling.
References
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Novel Type of Phase Transition in a System of Self-Driven Particles
TL;DR: Numerical evidence is presented that this model results in a kinetic phase transition from no transport to finite net transport through spontaneous symmetry breaking of the rotational symmetry.
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Self-organized criticality: An explanation of the 1/ f noise
TL;DR: It is shown that dynamical systems with spatial degrees of freedom naturally evolve into a self-organized critical point, and flicker noise, or 1/f noise, can be identified with the dynamics of the critical state.
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Theory of Dynamic Critical Phenomena
TL;DR: The renormalization group theory has been applied to a variety of dynamic critical phenomena, such as the phase separation of a symmetric binary fluid as mentioned in this paper, and it has been shown that it can explain available experimental data at the critical point of pure fluids, and binary mixtures, and at many magnetic phase transitions.
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Phase transitions and critical phenomena
TL;DR: The examination of phase transitions and critical phenomena has dominated statistical physics for the latter half of this century as discussed by the authors, and beautiful experimental results have elucidated the singularities (critical behavior) that occur in phase transitions.
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Liquid-liquid phase separation in biology.
TL;DR: The basic physical concepts necessary to understand the consequences of liquid-like states for biological functions are discussed.