Litcius/Paper detail

Room-Temperature Patterning of Nanoscale MoS<sub>2</sub> under an Electron Beam

Mohammad S. M. Saifullah, Mohamed Asbahi, Maryam Binti-Kamran Kiyani, Sing Shy Liow, Surani Bin Dolmanan, Anna Marie Yong, Esther A. H. Ong, Asadullah Ibn Saifullah, Hui Ru Tan, Neeraj Dwivedi, Tanmay Dutta, Ramakrishnan Ganesan, Suresh Valiyaveettil, Karen S. L. Chong, S. Tripathy

2020ACS Applied Materials & Interfaces18 citationsDOI

Abstract

Molybdenum disulfide (MoS2) is traditionally grown at a high temperature and subsequently patterned to study its electronic properties or make devices. This method imposes severe limitations on the shape and size of MoS2 crystals that can be patterned precisely at required positions. Here, we describe a method of direct nanoscale patterning of MoS2 at room temperature by exposing a molybdenum thiocubane single-source precursor to a beam of electrons. Molybdenum thiocubanes with various alkylxanthate moieties [Mo4S4(ROCS2)6, where R = alkyl] were prepared using a “self-assembly” approach. Micro-Raman and micro-FTIR spectroscopic studies suggest that exposure to a relatively smaller dose of electrons results in the breakdown of xanthate moieties, leading to the formation of MoS2. High-resolution transmission electron micrographs suggest that the growth of MoS2 most likely happens along (100) planes. An electron-beam-induced chemical transformation of a molybdenum thiocubane resist was exploited to fabricate sub-10 nm MoS2 lines and dense dots as small as 13 nm with a pitch of 33 nm. Since this technique does not require the liftoff and etching steps, patterning of MoS2 with interesting shapes, sizes, and thicknesses potentially leading to tunable band gap is possible.

Topics & Concepts

Materials scienceMolybdenum disulfideMolybdenumNanoscopic scaleResistRaman spectroscopyEtching (microfabrication)NanotechnologyOptoelectronicsCathode rayTransmission electron microscopyElectron-beam lithographyElectronOpticsComposite materialQuantum mechanicsPhysicsLayer (electronics)Metallurgy2D Materials and ApplicationsMXene and MAX Phase MaterialsChalcogenide Semiconductor Thin Films