Dynamic correlations in the conserved Manna sandpile
Abstract
We study dynamic correlations for current and mass, as well as the associated power spectra, in the one-dimensional conserved Manna sandpile. We show that, in the thermodynamic limit, the variance of cumulative bond current up to time T grows subdiffusively as T1/2-μ with the exponent μ 0 depending on the density regimes considered and, likewise, the power spectra of current and mass at low frequency f varies as f1/2+μ and f-3/2+μ, respectively; our theory predicts that, far from criticality, μ = 0 and, near criticality, μ = (β+1)/2 z > 0 with β, and z being the order-parameter, correlation-length and dynamic exponents, respectively. The anomalous suppression of fluctuations near criticality signifies a "dynamic hyperuniformity", characterized by a set of fluctuation relations, in which current, mass and tagged-particle displacement fluctuations are shown to have a precise quantitative relationship with the density-dependent activity (or, it's derivative). In particular, the relation, Ds() = a() / , between the self-diffusion coefficient Ds(), activity a() and density explains a previous simulation observation [Eur. Phys. J. B 72, 441 (2009)] that, near criticality, the self-diffusion coefficient in the Manna sandpile has the same scaling behavior as the activity.
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