Proximity effect and Anomalous metal state in a model of mixed metal-superconductor grains

Motivated by the discovery of the anomalous metal state in thin film systems and suggestions that coexistence of superconducting and metallic components is crucial to the formation of the state, we study in this paper a model of mixed metallic and superconducting grains coupled by electron tunneling - the metallic grains are expected to become superconducting because of proximity effect in a mean-field treatment of the model. When quantum fluctuations in relative phases between different grains are taken into account, we show that the proximity effect can be destroyed and the metallic and superconducting grains become "insulating" with respect to each other when the charging energy between grains are strong enough and tunneling between grains are weak enough, in analogy to superconductor-insulator transition in pure superconducting grains or metal-insulator transition in pure metallic grains. Based on this observation, a physical picture of how the anomalous metal state may form is proposed. An experimental setup to test our proposed physical picture is suggested.