Growth and preservation of entanglement in a many-body localized system

In non-interacting systems disorder leads to Anderson localization, where particle diffusion and entanglement propagation are absent. Interactions between the constituent particles modify this picture, leading to a many-body localized (MBL) phase. A key challenge is to measure interaction induced dynamics of entanglement between the localized sites in this phase. By studying interacting photons in an array of superconducting qubits, we observe ergodicity breaking and directly measure the effective non-local interactions. We probe the entanglement signatures of MBL in 1D and 2D and observe the slow growth of entanglement entropy. Finally, we characterize the potential of the MBL phase to be used as a quantum memory by demonstrating the slow decay of entanglement of a distant bell pair. Our work elucidates the fundamental mechanisms of entanglement formation, propagation, and preservation in the MBL phase of matter.