Beyond Lindblad Dynamics: Rigorous Guarantees for Thermal and Ground State Preservation under System Bath Interactions (2512.03457v1)

Abstract: We establish new theoretical results demonstrating the efficiency and robustness of system bath interaction models for quantum thermal and ground state preparation. Unlike existing analyses, which relies on the weak coupling Lindblad limit and require $O(ε)$ coupling strengths for $ε$ accuracy, leading to slow mixing, we rigorously show that accurate state preparation remains possible far beyond this regime. In particular, even when the cumulative coupling strength remains constant rather than vanishing, the induced quantum channel still approximately fixes the target state. Our proof introduces new techniques for controlling all orders of the Dyson expansion and for analyzing the associated multidimensional operator Fourier transforms. These bounds substantially improve upon prior results, and numerical simulations on the TFIM and Hubbard models further confirm the robustness of the system bath interaction framework across both weak and strong coupling regimes.