A new porous metallic silicon dicarbide for highly efficient Li-ion battery anode identified by targeted structure search

TL;DR

This paper introduces a novel porous metallic silicon dicarbide (T-C2Si) for Li-ion battery anodes, identified through targeted structure search, offering high capacity, conductivity, and minimal volume change, suitable for electric vehicle applications.

Contribution

The study applies a targeted structure search method using Li as a template to discover a new stable, porous, metallic silicon carbide phase with enhanced electrochemical properties.

Findings

T-C2Si has a specific capacity of 515 mA/g.

It exhibits a high average open-circuit voltage of 1.14 eV.

Volume change during operation is only 1.6%.

Abstract

Extensive efforts have been devoted to C-Si compound materials for improving the limited specific capacity of graphite anode and avoiding the huge volume change of Si anode in Li-ion battery, but not much progress has been made during the past decades. Here, for the first time we apply the targeted structure search by using Li in desired quantity as chemical template to regulate the bonding between C and Si, which makes searching more feasible for us to find a new stable phase of C2Si (labelled as T-C2Si) that can better fit the XRD data of silicon dicarbide synthesized before. Different from the conventional semiconducting silicon carbides, T-C2Si is not only metallic with high intrinsic conductivity for electrons transport, but also porous with regularly distributed channels in suitable size for Li ions experiencing a low energy barrier. T-C2Si exhibits a high specific capacity of 515 mA/g, a high average open-circuit voltage of 1.14 eV, and a low volume change of 1.6%. These parameters meet the requirements of an ideal anode material with high performance for electric vehicles. Moreover, our targeted search strategy guarantees the resulting anode material with a desirable specific capacity and a small volume change during charging /discharging, and it can be used to find new geometric configurations for other materials.