Two-dimensional transition-metal dichalcogenides have recently emerged as a promising material system. In particular, molybdenum (IV) sulfide (MoS2) films have been widely investigated as one of the most promising devices for next-generation electronic transistor applications. In this study, an MoS2 film consisting of small crystalline particles and containing a small amount of oxygen atoms substituted for sulfur atoms is deposited by radiofrequency sputtering. The film's optical bandgap is ~1.25 eV, and it exhibits p-type conduction properties. According to first-principles calculations, the oxygen doping produces a new state immediately above the valence band edge, which might explain the p-type conductivity of the as-sputtered MoS2 film. We fabricated p-channel thin-film transistors (TFTs). Simulation and Kelvin probe analysis of the TFT indicated that Cu is the most suitable material to make ohmic contact between the source and drain contacts among the metals we compared. The mobility of the TFT was found to be ~31.47 cm2/(V·s) initially. After the TFT was annealed at 200°C for 1 h in air, its mobility increased to 52.42 cm2/(V·s). Analyses by Raman spectroscopy and X-ray photoelectron spectroscopy indicated that the sputtered film contained numerous sulfur defects. To compensate for the defects, we carried out oxidization by hot-wire. As a result, the mobility increased to 62.73 cm2/(V·s). Moreover, to reduce the number metal–MoS2 interfaces at sulfur defects, a sulfide treatment was conducted at 200°C for 1 h. An ON/OFF ratio of 2.85×10−6 and mobility of 54.92 cm2/(V·s) were achieved after the sulfurization.
In this study, the relationships of the microstructures, the hardness distributions and the residual stress distributions with the laser scanning patterns were systematically investigated for a martensitic stainless steel SUS420J2 fabricated by laser powder bed fusion (AM material). The microstructures of the AM materials were consisted of mainly the needle-shaped α' phase, with the retained γ phase and the fine cementite particles. There was the Kurdjumov-Sachs relationship between the (011) plane of the α' phase and the (111) plane of the retained γ phase. The hardness of the AM materials was higher than that of the wrought material which was quenched and tempered. All AM materials had similar hardness since there were no significant differences in their microstructures, even though the scanning patterns were different. It was experimentally shown that the residual stresses of the AM materials can be reduced by changing the laser scanning patterns. Especially, the residual stress value was reduced by 75% using the chessboard-type scanning pattern with the alternating scanning directions and shifting the pattern.