A spectral model of power-law decay in natural and engineered systems

Abstract

We present a first-principles spectral mechanism for the emergence of nonextensive q-exponential dilution and power-law relaxation in non-ideal transport systems. By modeling an incompletely mixed reactor as a layered diffusion matrix with an absorbing boundary, we demonstrate that macroscopic power-law tails depend on the geometric interaction between the initial tracer placement and the domain's boundary configuration. For a one-dimensional system, an asymmetric, volumetrically distributed initial concentration profile projects onto the low-wavenumber eigenmodes, generating an emergent Gamma distribution of relaxation rates; at an infinitesimal boundary layer thickness (Δz 0), this profile yields the nonextensive q-exponential decay function exactly across the entire temporal domain with q = 5/3. Extended to d dimensions under a highly localized, boundary-adjacent singular initial condition, the resulting scaling exponents and corresponding q values depend explicitly on the spatial configuration of the absorbing boundaries. However, in the one-dimensional limit (d=1), these distinct initial states and boundary formulations intersect, rendering the q=5/3 exponent geometrically invariant. Our approach establishes a clear connection between linear diffusion transport and nonextensive statistical mechanics, showing how heavy-tailed transport can be derived from boundary geometry and spectral dimensionality.