Maximal steady-state entanglement in autonomous quantum thermal machines

We devise an autonomous quantum thermal machine consisting of three pairwise-interacting qubits, two of which are locally coupled to separate classical reservoirs. The machine operates autonomously, as it requires no time-coherent control, external driving or quantum bath engineering, and is instead propelled by a chemical potential bias between the reservoirs. Under ideal conditions, we show that this out-of-equilibrium system can deterministically generate a maximally entangled steady-state between two of the qubits, or in fact, any desired pure two-qubit entangled state, emerging as a dark state of the system. The entanglement production is also robust, such that nearly-maximally-entangled states can be generated well-away from the ideal regime of operation. Furthermore, we show that our machine architecture can be generalised to a configuration with $2n-1$ qubits, in which only a potential bias and two-body interactions are sufficient to generate genuine multipartite maximally entangled steady states in the form of a W state of $n$ qubits.