Litcius/Paper detail

Recessed-Channel WSe<sub>2</sub> Field-Effect Transistor via Self-Terminated Doping and Layer-by-Layer Etching

Dongryul Lee, Yongha Choi, Jung-Hun Kim, Junghun Kim, Jihyun Kim, Jihyun Kim

2022ACS Nano33 citationsDOI

Abstract

Effective channel control with low contact resistance can be accomplished through selective ion implantation in Si and III–V semiconductor technologies; however, this approach cannot be adopted for ultrathin van der Waals materials. Herein, we demonstrate a self-aligned fabrication process based on self-terminated p-doping and layer-by-layer chemical etching to achieve low contact resistance as well as a high on/off current ratio in ultrathin tungsten diselenide (WSe2) field-effect transistors (FETs). Damage-free layer-by-layer thinning of the WSe2 channel is repeated up to a thickness of approximately 1.4 nm, while maintaining the selectively p-doped source/drain regions. The device characteristics of the recessed-channel WSe2 FET are systematically monitored during this layer-by-layer recess-channel process. The WSe2 etching rate is estimated to be 2–3 layers per cycle of oxidation and subsequent chemical etching. The self-terminated tungsten oxide (WOX) layer grown through ultraviolet–ozone treatment induces robust p-doping in the neighboring (or underlying) WSe2 through the electron withdrawal mechanism, which remains in the source/drain regions after channel oxide removal. The adopted self-terminated and self-aligned recess-channel process for ultrathin WSe2 FETs enables the realization of a high on/off output current ratio (>108) and field-effect mobility (∼190 cm2/V·s), while maintaining low contact resistance (0.9–6.1 kΩ·μm) without a postannealing process. The proposed facile and reproducible doping and atomic-layer-etching method for the fabrication of a recessed-channel FET with an ultrathin body can be helpful for high-performance two-dimensional semiconductor devices and is applicable to post-Si complementary metal-oxide semiconductor devices.

Topics & Concepts

Materials scienceEtching (microfabrication)Layer (electronics)DopingOptoelectronicsField-effect transistorTransistorChannel (broadcasting)NanotechnologyElectrical engineeringVoltageEngineering2D Materials and ApplicationsAdvanced Memory and Neural ComputingMolecular Junctions and Nanostructures