High-Throughput Computational Design of 2D Ternary Chalcogenides for Sustainable Energy.
Penghua LanNaihua MiaoYu GanLiyu PengSiyu HanJian ZhouZhi-Mei SunPublished in: The journal of physical chemistry letters (2023)
Two-dimensional materials are considered to be promising for next-generation electronic and energy devices. However, the limited availability of 2D materials hinders their applications. Herein, we employed high-throughput computation to discover new 2D materials by cleaving the bulk and to investigate their electronic, thermoelectric, and optoelectronic properties. Using our database containing 810 structures of chalcogenides ABX 3 (A or B = Al, Ga, In, Si, Ge, Sn, P, As, Sb, and Bi; X = S, Se, and Te), we identified 204 new 2D compounds promising for experimental preparation according to the exfoliation energy. Notably, 96 of them are more easily exfoliated than graphene, 52 compounds show higher Seebeck coefficients than Bi 2 Te 3 at 300 K, and 20 compounds have power factors beyond 2 × 10 -3 Wm -1 K -2 at 900 K. Also, 6 new compounds exhibit high theoretical photovoltaic efficiency exceeding 30%. Our findings expand the 2D materials family and provide new 2D compounds for sustainable thermoelectric and optoelectronic energy applications.