Tin Metal Improves the Lithiation Kinetics of High-Capacity Silicon Anodes
Yao Kang, Na Li, Ning Li, Eric Sivonxay, Yaping Du, Kristin A. Persson, Dong Su, Wei Tong
Abstract
Si-based anodes present a great promise for high energy density lithium-ion batteries. However, its commercialization is largely hindered by a grand challenge of a rapid capacity fade. Here, we demonstrate excellent cycling stability on a Si–Sn thin film electrode that outperforms pure Si or Sn counterpart under the similar conditions. Combined with the first-principles calculations, in situ transmission electron microscopy studies reveal a reduced volume expansion, increased conductivity, as well as dynamic rearrangement upon lithiation of the Si–Sn film. We attribute the improved lithiation kinetics to the formation of a conductive matrix that comprises a mosaic of nanostructured Sn, Li y Sn (specifically, Li 7 Sn 2 develops around the lithiation potential of Si), and Li x Si. This work provides an important advance in understanding the lithiation mechanism of Si-based anodes for next-generation lithium-ion batteries.