Silicon monoxide has a bit higher g

Silicon monoxide has a bit higher gravimetric capacity(2043 mA h g
1) than traditional anode materials, and it has become one of the most attractive materials for Li-ion battery anode
[1]. However, the large volume change during the lithiation/delithiation processes hinders its practical applications and leads to a poor cycle performance. For the improvement of the volume capacity and the cyclic stability of silicon anodes, many methods have been evaluated to prevent the collapse of silicon anode and increase the stability of the solid electrolyte interphase (SEI) layer. These methods include the development of Si materials composed of nanostructures [2], porous structures [3,4], or nanocomposites [5], the addition of coating layers [6], and the application of electrolyte additives and novel binders [7]. Among all these methods, a hollow core–shell structure is one of the most attractive candidates to enhance structural stability [8,9]. A hollow structure in the Si–C nanocomposite can further buffer the volume change of the silicon materials, and core–shell-structured materials have been recognized as the most promising materials for anodes in lithium-ion batteries (LIBs). Experimental studies involving
carbon-coated silicon anode materials or hollow silicon structures have been carried out by previous investigators [8,9]. Inspired by these studies, we developed a novel solution growth method to synthesize novel anode materials with core– shell structures for LIBs. The synthesis process is easy to control, and all the chemicals used are environmentally friendly. As a result, a high specific capacity and a long cycle life have been achieved.