Intermittency-Driven Turbulence Cascade Memory Extends the Markov-Einstein Coherence Length Beyond the Canonical Estimate

Abstract

Using direct numerical simulation of forced isotropic turbulence at Reλ ≈ 1300 and ≈ 433, together with two independent Markov-by-construction null surrogates, we measure the Markov--Einstein coherence length of the turbulent energy cascade to be r ≈ 3.2-3.6 in log-scale cascade coordinates, approximately three times the canonical estimate r ≈ 1. Stratifying the gap-scan test by local dissipation intensity and by increment amplitude reveals that intermittent events carry r ≈ 3-4, while at mid-inertial-range scales the quiescent cascade recovers r ≈ 1.0-1.4, consistent with the canonical value. Near the dissipation range this pattern reverses: bulk dynamics carry more memory than extreme events, consistent with the spectral bottleneck. The excess memory is internal to the inertial range and Reynolds-number-independent over Reλ ≈ 433-1300. These findings indicate that the Markov approximation underlying the cascade Fokker-Planck equation and fluctuation-theorem analyses is substantially more restrictive than previously assumed, and that a non-Markovian correction, informed by the amplitude-dependent memory structure identified here, is needed for the intermittent component of the cascade.