A universal 2D-on-SiC platform for heterogeneous integration of epitaxial III-N membranes.
Se H Kim, Hanjoo Lee, Dong-Gwan Kim, Donghan Kim, Seokgi Kim, Hyunsoo Kim, Seoyong Ha, Hyunho Yang, Yunsu Jang, Jangho Yoon, ByoungTak Lee, Jung-Hee Lee, Roy Byung Kyu Chung, Hongsik Park, Sungkyu Kim
Abstract
Open AccessNonconventional epitaxial techniques, such as van der Waals epitaxy and remote epitaxy, have attracted substantial attention in the semiconductor research community for their capability to repeatedly produce high-quality freestanding films from a single mother wafer. Successful implementation of these techniques depends on creating a robust, uniform two-dimensional (2D) material surface. The conventional method for fabricating graphene on silicon carbide (SiC) is high-temperature graphitization. However, the extremely high temperature required for silicon sublimation (typically above 1500°C) causes step bunching, forming nonuniform multilayer graphene stripes and an unfavorable surface morphology for epitaxial growth. Here, we developed a wafer-scale graphitization technique that allows fast synthesis of single-crystalline graphene at low temperatures by metal-assisted graphitization. In contrast to previous reports, we found annealing conditions enabling SiC dissociation while avoiding silicide formation, producing uniform single-crystalline graphene while maintaining the pristine surface morphology of the substrate. We successfully produce high-quality freestanding single-crystalline III-N (AlN and GaN) membranes on graphene/SiC via the 2D material-based layer transfer technique.