Experimental Realization of Atomic Monolayer Si<sub>9</sub>C<sub>15</sub>
Zhao‐Yan Gao, Wenpeng Xu, Yixuan Gao, Roger Guzmán, Hui Guo, Xueyan Wang, Qi Zheng, Zhili Zhu, Yuyang Zhang, Xiao Lin, Qing Huan, Geng Li, Lizhi Zhang, Wu Zhou, Hong‐Jun Gao
Abstract
Abstract Monolayer Si x C y constitutes an important family of 2D materials that is predicted to feature a honeycomb structure and appreciable bandgaps. However, due to its binary chemical nature and the lack of bulk polymorphs with a layered structure, the fabrication of such materials has so far been challenging. Here, the synthesis of atomic monolayer Si 9 C 15 on Ru (0001) and Rh(111) substrates is reported. A combination of scanning tunneling microscopy (STM), X‐ray photoelectron spectroscopy (XPS), scanning transmission electron microscopy (STEM), and density functional theory (DFT) calculations is used to infer that the 2D lattice of Si 9 C 15 is a buckled honeycomb structure. Monolayer Si 9 C 15 shows semiconducting behavior with a bandgap of ≈1.9 eV. Remarkably, the Si 9 C 15 lattice remains intact after exposure to ambient conditions, indicating good air stability. The present work expands the 2D‐materials library and provides a promising platform for future studies in nanoelectronics and nanophotonics.