Zhou Liujiang, Dong Huilong, Tretiak Sergei
Institute of Fundamental and Frontier Sciences, University of Electronic Science and Technology of China, Chengdu 610054, P. R. China.
Nanoscale. 2020 Feb 21;12(7):4269-4282. doi: 10.1039/c9nr08755a. Epub 2020 Feb 10.
Compared to graphene with semimetallic features, two-dimensional (2D) silicon carbide (Si-C) materials constitute another highly promising family for opto-electronic applications owing to their intrinsic electronic gaps. Recent theoretical studies of 2D Si-C materials thoroughly investigated their structure and properties. Herein, we overview these high-throughput approaches aiming to theoretically design 2D Si-C crystals. Graphene-like siligraphene and non-siligraphene are described in terms of morphology, physicochemical properties and potential applications based on the insights provided by simulations. In addition, the current progress of experimental exploration of 2D Si-C materials and underlying challenges are assessed as well.
与具有半金属特性的石墨烯相比,二维(2D)碳化硅(Si-C)材料因其固有的电子能隙而成为光电子应用中另一个极具潜力的材料家族。最近对二维Si-C材料的理论研究深入探讨了它们的结构和性质。在此,我们概述了这些旨在从理论上设计二维Si-C晶体的高通量方法。基于模拟提供的见解,从形态、物理化学性质和潜在应用等方面描述了类石墨烯的硅石墨烯和非硅石墨烯。此外,还评估了二维Si-C材料实验探索的当前进展以及潜在挑战。
