The dynamical α-R\'enyi entropies of local Hamiltonians grow at most linearly in time

Abstract

We consider a generic one dimensional spin system of length L , arbitrarily large, with strictly local interactions, for example nearest neighbor, and prove that the dynamical α -R\'enyi entropies, 0 < α 1 , of an initial product state grow at most linearly in time. This result arises from a general relation among dynamical α -R\'enyi entropies and Lieb-Robinson bounds. We extend our bound on the dynamical generation of entropy to systems with exponential decay of interactions, for values of α close enough to 1 , and moreover to initial pure states with low entanglement, of order L , that are typically represented by critical states. We establish that low entanglement states have an efficient MPS representation that persists at least up to times of order L . The main technical tools are the Lieb-Robinson bounds, to locally approximate the dynamics of the spin chain, a strict upper bound of Audenaert on α -R\'enyi entropies and a bound on their concavity. Such a bound, that we provide in an appendix, can be of independent interest.