Universal cooling of quantum systems via randomized measurements

Abstract: It is generally believed that the design of cooling protocols requires knowledge of the system's spectrum. In contrast, cooling processes in nature occur whenever the system is coupled to a cold bath. But how does nature know how to cool quantum systems? Here we address this question by mimicking a natural cold bath with a reservoir of "meter" qubits that are initialized in their ground state and interact with the system sequentially for a specified time before being discarded. This protocol is equivalent to quantum measurements without keeping the measurement readouts. We show that a quantum system can be cooled without prior knowledge of the system's details when the interactions between the system and the meters, as well as the level splittings of the meters, are chosen randomly. For sufficiently small interaction strengths and long interaction times, the rotating-wave approximation becomes valid, ensuring that resonant energy-exchange processes, which lead to cooling, dominate over heating. This demonstrates that robust and scalable cooling of complex quantum systems can be achieved through generic, structure-independent protocols. Our findings thus offer a versatile universal framework for engineering, controlling, and manipulating quantum matter far from equilibrium, in particular, for the purposes of quantum information processing and quantum simulations.