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Finite-size scaling as a way to probe near-criticality in natural swarms

Collective behaviour in biological systems is often accompanied by strong correlations. The question has therefore arisen of whether correlation is amplified by the vicinity to some critical point in the parameters space. Biological systems, though, are typically quite far from the thermodynamic limit, so that the value of the control parameter at which correlation and susceptibility peak depend on size. Hence, a system would need to readjust its control parameter according to its size in order to be maximally correlated. This readjustment, though, has never been observed experimentally. By gathering three-dimensional data on swarms of midges in the field we find that swarms tune their control parameter and size so as to maintain a scaling behaviour of the correlation function. As a consequence, correlation length and susceptibility scale with the system's size and swarms exhibit a near-maximal degree of correlation at all sizes.

preprint2014arXivOpen access
A. AttanasiA. CavagnaL. Del CastelloI. GiardinaS. MelilloL. ParisiO. PohlB. RossaroE. ShenE. SilvestriM. Viale
cond-mat.stat-mechBiological PhysicsPopulations and Evolution
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A. AttanasiA. CavagnaL. Del CastelloI. GiardinaS. MelilloL. ParisiO. PohlB. RossaroE. ShenE. SilvestriM. Viale

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