Chapter 8. Self-Organized Criticality
In the previous chapter we saw an example of a system with a critical point and we explored one of the common properties of critical systems, fractal geometry.
In this chapter, we explore two other properties of critical systems: heavy-tailed distributions, which we saw in “Heavy-Tailed Distributions” and pink noise, which I’ll explain in this chapter.
These properties are interesting in part because they appear frequently in nature; that is, many natural systems produce fractal-like geometry, heavy-tailed distributions, and pink noise.
This observation raises a natural question: why do so many natural systems have properties of critical systems? A possible answer is self-organized criticality (SOC), which is the tendency of some systems to evolve toward, and stay in, a critical state.
In this chapter I’ll present a sand pile model that was the first system shown to exhibit SOC.
Critical Systems
Many critical systems demonstrate common behaviors:
Fractal geometry: For example, freezing water tends to form fractal patterns, including snowflakes and other crystal structures. Fractals are characterized by self-similarity; that is, parts of the pattern are similar to scaled copies of the whole.
Heavy-tailed distributions of some physical quantities: For example, in freezing water the distribution of crystal sizes is characterized by a power law.
Variations in time that exhibit pink noise: complex signals can be decomposed into their frequency components. ...
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