Universal energy-space localization and stable quantum phases against time-dependent perturbations (2510.14160v1)

Abstract: Stability against perturbation is a highly nontrivial property of quantum systems and is often a requirement to define new phases. In most systems where stability can be rigorously established, only static perturbations are considered; whether a system is stable against generic time-dependent perturbations remains largely elusive. In this work, we identify a universal phenomenon in $q$-local Hamiltonians called energy-space localization and prove that it can survive under generic time-dependent perturbations, where the evolving state is exponentially localized in an energy window of the instantaneous spectrum. The property holds ubiquitously, and the leakage bounds remain invariant under arbitrarily monotonic rescaling of evolution time. This flexibility enables the energy-space localization to be a powerful tool in proving the stability of systems. For spin glass models where the configuration spaces are separated by large energy barriers, the localization in energy space can induce a true localization in the configuration space and robustly break ergodicity. We then demonstrate the applications of our results in several systems with such barriers. For certain LDPC codes, we show that the evolving state is localized near the original codeword for an exponentially long time even under generic time-dependent perturbations. We also extend the stability of LDPC codes against static $q$-local perturbations to quasi-$q$-local. In addition, we show that for some classical hard optimization problems with clustered solution space, the stability becomes an obstacle for quantum Hamiltonian-based algorithms to drive the system out of local minima. Our work provides a new lens for analyzing the non-equilibrium dynamics of generic quantum systems, and versatile mathematical tools for stability proving and quantum algorithm design.