Abstract
2D materials beyond molybdenum disulfide such as molybdenum ditelluride (MoTe2) have attracted increasing attention because of their distinctive properties, such as phase-engineered, relatively narrow direct bandgap of 1.0–1.1 eV and superior carrier transport. However, a wafer-scale synthesis process is required for achieving practical applications in next-generation electronic devices using MoTe2 thin films. Herein, the direct growth of atomically thin 1T′, 1T′–2H mixed, and 2H phases MoTe2 films on a 4 in. SiO2/Si wafer with high spatial uniformity (≈96%) via metal–organic vapor phase deposition is reported. Furthermore, the wafer-scale phase engineering of few-layer MoTe2 film is investigated by controlling the H2 molar flow rate. While the use of a low H2 molar flow rate results in 1T′ and 1T′–2H mixed phase MoTe2 films, 2H phase MoTe2 films are obtained at a high H2 molar flow rate. Field-effect transistors fabricated with the prepared 2H and 1T′ phases MoTe2 channels reveal p-type semiconductor and semimetal properties, respectively. This work demonstrates the potential for reliable wafer-scale production of 1T′ and 2H phases MoTe2 thin films employing the H2 molar flow rate-controlled phase tunable method for practical applications in next-generation electronic devices as a p-type semiconductor and Wyle semimetal.
Original language | English |
---|---|
Article number | 1800439 |
Journal | Advanced Materials Interfaces |
Volume | 5 |
Issue number | 15 |
DOIs | |
State | Published - 9 Aug 2018 |
Keywords
- 1T′ and 2H phase MoTe
- H flow rate
- metal–organic chemical vapor deposition
- phase engineering
- wafer-scale synthesis