Measurement-based quantum repeaters

We introduce measurement-based quantum repeaters, where small-scale measurement-based quantum processors are used to perform entanglement purification and entanglement swapping in a long-range quantum communication protocol. In the scheme, preprepared entangled states stored at intermediate repeater stations are coupled with incoming photons by simple Bell measurements, without the need of performing additional quantum gates. We show how to construct the required resource states, and how to minimize their size. We analyze the performance of the scheme under noise and imperfections, with focus on small-scale implementations involving entangled states of few qubits. We find measurement-based purification protocols with significantly improved noise thresholds. Furthermore we show that resource states of small size suffice to significantly increase the maximal communication distance. We also discuss possible advantages of our scheme for different setups.