Length-resolved Operator Growth and Path-Entropy Obstructions to Many-Body Localization

Abstract

For the disordered Ising chain with transverse and longitudinal fields, where couplings and fields are drawn from strictly positive distributions, Cao~Cao has shown that the moments μ2k = \|[H,σz0](k)\|22 grow almost factorially, μ2k1/(2k) k/ k, and thus asymptotically at the maximal allowed rate. We generalize this result by resolving the operator norm in support length and show that the weight at length k k/ k already exhibits almost factorial growth, \|[H,σz0](k)_k\|2 (k/ k)k. This implies maximal spatial delocalization of local operators and, in particular, rules out dynamical locality -- the strongest form of many-body localization -- at any disorder strength. We further establish rigorously a finite-size crossover scale L (W/J)2, where W is the disorder and J the coupling strength. For L (W/J)2 numerical studies only access a pre-asymptotic regime. Finally, we identify a structural path-entropy obstruction to perturbative LIOM constructions, based on the almost factorial branching of operator content and independent of resonance effects; the same mechanism strongly suggests ballistic real-time operator spreading, so sub-ballistic or localized dynamics would require a presently unidentified cancellation principle acting on almost factorially many disorder-dependent paths with random amplitudes.