In this study, copper oxide thin films were fabricated by facing target sputtering system and their structural, optical, and electrical properties were investigated. Crystal phase of samples were changed by variation of oxygen flow rate from Cu to Cu₂O and CuO. Compared to Cu metal film, electrical properties of Cu₂O and CuO were relatively degraded, however, asfabricated Cu₂O and CuO indicated still low resistivity (~10-3 Ω·cm) and high carrier concentration (~1019 cm-3). From the results, it is thought that the copper oxide thin films Cu₂O fabricated under optimal conditions can be applied to various optoelectronic devices including ultraviolet photodetector.
We investigated solution-processed indium-zinc oxide (IZO) thin-film transistors (TFTs) by inserting a 2-(4- biphenylyl)-5-(4-tert-butylphenyl)-1,3,4-oxadiazole (PBD) buffer layer. This buffer layer efficiently tuned the energy level between the semiconducting oxide channel and metal electrode by increasing charge extraction, thereby enhancing the overall device performance: the IZO TFT with embedded PBD layer (thickness: 5 nm; width: 2,000 μm; length: 200 μm) exhibited a field-effect mobility of 1.31 cm2V-1s-1, threshold voltage of 0.12 V, subthreshold swing of 0.87 V decade-1, and on/off current ratio of 9.28×105.
We investigated solution-processed indium-yttrium-oxide (IYO) TFTs using apoly (methyl methacrylate) (PMMA) passivation layer. The IYO semiconductor solution was prepared with 0.1 M indium nitrate hydrate and 0.1 M yttrium acetate dehydrate as precursor solutions. The solution-processed IYO TFTs showed good performance: field-effect mobility of 13.13 ㎠/Vs, a threshold voltage of 8.2 V, a subthreshold slope of 0.93 V/dec, and a current on-to-off ratio of 7.2 × 106. Moreover, the PMMA passivation layers used to protectthe IYO active layer of the TFTs, did so without deteriorating their performance under ambient conditions; their operational stability and electrical properties also improved by decreasing leakage current.
The ultimate aims of display market is transparent or flexible. Researches have been carried out for various applications. It has been possible to reduced the process steps and get good electrical properties for semiconductors with large optical bandgaps. Oxide semiconductors have been established as one of the leading and promising technology for next generation display panels. In this paper, alternative treatment processes have been tried for oxide semiconductors of thin film transistors to increase the electrical properties of the thin film transistors and to investigate the mechanisms. There exist a various oxide semiconductors. Here, we focused on InGaZnO, ZnO and InSnZnO which are commercialized or researched actively.
In this research, we prepared Ga doped zinc oxide(ZnO:Ga, GZO) targets each difference sintering temperature 700℃, 800℃, and doping rate 1 wt.%, 2 wt.%, 3 wt.%. The characteristics of thin film on glass substrates which deposited by facing target sputtering in pure Ar atmosphere are reported. Ga doped zinc oxide film is attracted material through low resistivity, high transmittance, etc. When prepared target powder`s structure was investigated by scanning electron microscope, densification and coarsening by driving force was observed. For each ZnO:Ga films with a Ga2O3 content of 3 wt.% at input power of 45 W, the lowest resistivity of 9.967×10(-4) Ω·cm (700℃) and 9.846×10(-4) Ω ·cm (800℃) was obtained. the carrier concentration and mobility were 4.09 × 10(20) cm-3(700℃), 4.12×10(20) cm-3(800℃) and 15.31 cm2/V·s(700℃), 12.51 cm2/V·s(800℃), respectively. And except 1 wt.% Ga doped ZnO thin film, average transmittance of these samples in the range 350-800 nm was over 80%.