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Realizing Large-Scale, Electronic-Grade Two-Dimensional Semiconductors.

Yu-Chuan LinBhakti JariwalaBrian M BerschKe XuYifan NieBaoming WangSarah M EichfeldXiaotian ZhangTanushree H ChoudhuryYi PanRafik AddouChristopher M SmythJun LiKehao ZhangM Aman HaqueStefan FölschRandall M FeenstraRobert M WallaceKyeongjae ChoSusan K Fullerton-ShireyJoan Marie RedwingJoshua A Robinson
Published in: ACS nano (2018)
Atomically thin transition metal dichalcogenides (TMDs) are of interest for next-generation electronics and optoelectronics. Here, we demonstrate device-ready synthetic tungsten diselenide (WSe2) via metal-organic chemical vapor deposition and provide key insights into the phenomena that control the properties of large-area, epitaxial TMDs. When epitaxy is achieved, the sapphire surface reconstructs, leading to strong 2D/3D (i.e., TMD/substrate) interactions that impact carrier transport. Furthermore, we demonstrate that substrate step edges are a major source of carrier doping and scattering. Even with 2D/3D coupling, transistors utilizing transfer-free epitaxial WSe2/sapphire exhibit ambipolar behavior with excellent on/off ratios (∼107), high current density (1-10 μA·μm-1), and good field-effect transistor mobility (∼30 cm2·V-1·s-1) at room temperature. This work establishes that realization of electronic-grade epitaxial TMDs must consider the impact of the TMD precursors, substrate, and the 2D/3D interface as leading factors in electronic performance.
Keyphrases
  • room temperature
  • transition metal
  • ionic liquid
  • amino acid
  • electron transfer