[摘要] Garnet-type solid-state electrolytes (SSEs) are a remarkable Li-ion electrolyte for the realization of next-generation all-solid-state lithium batteries due to their excellent stability against Li metal as well as high ionic conductivities at room temperature. However, garnet electrolytes always contain undesired and hardly removable Li 2 CO 3 contaminations that have persistently large resistance and unstable interface contact with Li metal. This is a critical bottleneck for the practical application of garnet electrolytes. Here, we design a novel strategy to completely root out Li 2 CO 3 both inside and on the surface of garnet. This is achieved by a so-called double replacement reaction between Li 2 CO 3 and SiO 2 during one-step hot press process for garnet electrolyte densification. It leads to in-situ transformation of Li x SiO y (LSO) mostly locating around the grain boundaries of garnet. Due to the higher ion conductivity and better electrochemistry stability of LSO than Li 2 CO 3 , the modified garnet electrolyte shows much improved electrochemical performance. Moreover, the wettability between modified garnet electrolyte and lithium metals was significantly enhanced in the absence of surface Li 2 CO 3 . As a proof of concept, an assembled Li symmetric cell with modified garnet electrolyte displays a high critical current density (CCD) of 0.7 mA cm −2 and a low interfacial impedance (5 Ω cm 2 ) at 25 °C. These results indicate that the upcycling of Li 2 CO 3 is a promising strategy to well-address the degradation and interfacial issue associated with garnet electrolytes.