Fast and direct preparation of a genuine lattice BEC via the quantum Mpemba effect

We present an efficient method for dissipatively preparing a Bose-Einstein condensate (BEC) directly on a lattice, avoiding the need for a two-staged preparation procedure currently used in ultracold atom platforms. Our protocol is based on driving the lattice-subsystem into a non-equilibrium steady state, which we show to exhibit a lattice analog of a true BEC, where the depletion can be controlled via the dissipation strength. Furthermore, exploiting a symmetry-based Mpemba effect, we analytically identify a class of simple, experimentally-realizable states that converge exponentially faster to the steady state than typical random initializations. We also show how to tune the momentum of the created high-fidelity BEC by combining superfluid immersion with lattice shaking. Our theoretical predictions are confirmed by numerical simulations of the dissipative dynamics, quantitatively assessing the speedups yielded by our protocol, as well as the fidelities of the prepared BEC.