Abstract
Although the silicon (Si) anode has a high theoretical capacity, large volume-expansion would lead to rapid capacity decay. Here, a core-nest structured Si@SnS(0.5)Se(0.5)/carbon (Si@SnS(0.5)Se(0.5)/C) is developed using silicon as the core and SnS(0.5)Se(0.5)/carbon as a binary nest. Both the core-nest structure and carbon matrix enable a stable hybrid structure during charge and discharge. The binary nest Si@SnS(0.5)Se(0.5)/C nanospheres as a lithium-ion battery anode display good capacity, recoverable rate-performance, and enhanced electron and ion transfer properties. A capacity of 1318 mA h g(-1) and a high coulombic efficiency of 98.9% after 50 cycles at 0.1 A g(-1) are achievable, and the capacity remains 887 mA h g(-1) after 150 cycles at 0.5 A g(-1). A high capacity at 50 °C is also retained, showing a high initial specific capacity. It is found that the reaction resistance of Si@SnS(0.5)Se(0.5)/C is significantly lower than that of the pure components, and the stress-strain relationship of the Li-Si system is demonstrated by density functional theory (DFT) calculations. The engineering of the binary-nest structure should be able to provide some new ideas for developing many other high-performance energy-storage hybrids.