Atomically Controlled Tunable Doping in High‐Performance WSe<sub>2</sub> Devices
Chin‐Sheng Pang, Terry Y. T. Hung, Ava Khosravi, Rafik Addou, Qingxiao Wang, Moon J. Kim, Robert M. Wallace, Zhihong Chen
Abstract
Abstract 2D transitional metal dichalcogenide (TMD) field‐effect transistors are promising candidates for future electronic applications, owing to their potential for ultimate device scaling. However, it is acknowledged that substantial contact resistance associated with the contact‐TMD interface has impeded device performance to a large extent. It has been discovered that O 2 plasma treatment can convert WSe 2 into WO 3− x and substantially improve contact resistances of p‐type WSe 2 devices by strong doping induced thinner depletion width. In this paper, temperature dependence of this conversion is studied, demonstrating an oxidation process with a precise monolayer control at room temperature and multilayer conversion at elevated temperatures. Furthermore, lateral oxidation of WSe 2 underneath contact revealed by high‐resolution scanning transmission electron microscope leads to potential unpinning of the metal Fermi level and Schottky barrier lowering, resulting in lower contact resistances. The p‐doping effect is attributed to the high electron affinity of the WO 3− x layer on top of the remaining WSe 2 channel, and the doping level is dependent on the WO 3− x thickness that is controlled by the temperature. Comprehensive materials and electrical characterizations are presented, with a low contact resistance of ≈528 Ω μm and record high on‐state current of 320 μA μm −1 at −1 V bias being reported.