High capacity and stable all-solid-state Li ion battery using SnO(2)-embedded nanoporous carbon

Extensive research efforts are devoted to development of high performance all-solid-state lithium ion batteries owing to their potential in not only improving safety but also achieving high stability and high capacity. However, conventional approaches based on a fabrication of highly dense electrode and solid electrolyte layers and their close contact interface is not always applicable to high capacity alloy- and/or conversion-based active materials such as SnO(2) accompanied with large volume change in charging-discharging. The present work demonstrates that SnO(2)-embedded nanoporous carbons without solid electrolyte inside the nanopores are a promising candidate for high capacity and stable anode material of all-solid-state battery, in which the volume change reactions are restricted in the nanopores to keep the constant electrode volume. A prototype all-solid-state full cell consisting of the SnO(2)-based anode and a LiNi(1/3)Co(1)/(3)Mn(1/3)O(2)-based cathode shows a good performance of 2040 Wh/kg at 268.6 W/kg based on the anode material weight.