Cornertronics in Two-Dimensional Second-Order Topological Insulators

Traditional electronic devices rely on electron's intrinsic degrees of freedom (d.o.f.) to process information. However, additional d.o.f. like the valley, can emerge in the low-energy states of certain systems. Here, we show that the quantum dots (QDs) constructed from two-dimensional (2D) second-order topological insulator (SOTI) posses a new kind of d.o.f., namely corner freedom, related to the topological corner states that reside at different corners of the systems. Since the corner states are well separated in real space, they can be intuitively addressed and manipulated individually, giving rise to the concept of cornertronics. Via symmetry analysis and material search, we identify the TiSiCO-family monolayers as the first prototype of cornertronics materials, where the corner states can be controlled by both electric and optical fields, due to the novel corner-layer coupling (CLC) effect and the corner-contrasted optical selection rules. Furthermore, we find that the band gap of the TiSiCO nanodisk lies in the terahertz region and is robust to size reduction. These results indicate that the TiSiCO nanodisks can be used to design terahertz devices with ultrasmall size, electric-field tunable band gap, and the ability to simultaneously detect the strength and polarization of terahertz waves, which is not possible for previously reported QDs. Our findings not only pave the way for the cornertronics, but also open a new direction for the research in 2D SOTI, QD and terahertz electronics.