Sub-ballistic operator growth in spin chains with heavy-tailed random fields

Abstract

We rigorously prove that in nearly arbitrary quantum spin chains with power-law-distributed random fields, namely such that the probability of a field exceeding h scales as h-α, it is impossible for any operator evolving in the Heisenberg picture to spread with dynamical exponent less than 1/α. In particular, ballistic growth is impossible for α < 1, diffusive growth is impossible for α < 1/2, and any finite dynamical exponent becomes impossible for sufficiently small α. This result thus establishes a wide family of models in which the disorder provably prevents conventional transport. We express the result as a tightening of Lieb-Robinson bounds due to random fields -- the proof modifies the standard derivation such that strong fields appear as effective weak interactions, and then makes use of analogous recent results for random-bond spin chains.