Sung Haeng Cho scite author profile

The ultimate transparent electronic devices require complementary and symmetrical pairs of n-type and p-type transparent semiconductors. While several n-type transparent oxide semiconductors like InGaZnO and ZnO are available and being used in consumer electronics, there are practically no p-type oxides that are comparable to the n-type counterpart in spite of tremendous efforts to discover them. Recently, high-throughput screening with the density functional theory calculations attempted to identify candidate p-type transparent oxides, but none of suggested materials was verified experimentally, implying need for a better theoretical predictor. Here, we propose a highly reliable and computationally efficient descriptor for p-type dopability—the hydrogen impurity energy. We show that the hydrogen descriptor can distinguish well-known p-type and n-type oxides. Using the hydrogen descriptor, we screen most binary oxides and a selected pool of ternary compounds that covers Sn2+-bearing and Cu1+-bearing oxides as well as oxychalcogenides. As a result, we suggest La2O2Te and CuLiO as promising p-type oxides.

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Effect of hydrogen diffusion in an In–Ga–Zn–O thin film transistor with an aluminum oxide gate insulator on its electrical properties

Nam

Kim

Cho

et al. 2018

RSC Adv.

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We fabricated amorphous InGaZnO thin film transistors (a-IGZO TFTs) with aluminum oxide (Al 2 O 3 ) as a gate insulator grown through atomic layer deposition (ALD) method at different deposition temperatures (T dep ). The Al 2 O 3 gate insulator with a low T dep exhibited a high amount of hydrogen in the film, and the relationship between the hydrogen content and the electrical properties of the TFTs was investigated. The device with the Al 2 O 3 gate insulator having a high H content showed much better transfer parameters and reliabilities than the low H sample. This is attributed to the defect passivation effect of H in the active layer, which is diffused from the Al 2 O 3 layer. In addition, according to the postannealing temperature (T post-ann ), a-IGZO TFTs exhibited two unique changes of properties; the degradation in low T post-ann and the enhancement in high T post-ann , as explained in terms of H diffusion from the gate insulator to an active layer.

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Spectroscopy and energy disposal dynamics of phthalocyanine–Ar (n=1,2) complexes generated by hyperthermal pulsed nozzle source

Cho

Yoon

Kim

2000

Chemical Physics Letters

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Impact of transient currents caused by alternating drain stress in oxide semiconductors

Lee

Cho²,

Abe³

et al. 2017

Sci Rep

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Reliability issues associated with driving metal-oxide semiconductor thin film transistors (TFTs), which may arise from various sequential drain/gate pulse voltage stresses and/or certain environmental parameters, have not received much attention due to the competing desire to characterise the shift in the transistor characteristics caused by gate charging. In this paper, we report on the reliability of these devices under AC bias stress conditions because this is one of the major sources of failure. In our analysis, we investigate the effects of the driving frequency, pulse shape, strength of the applied electric field, and channel current, and the results are compared with those from a general reliability test in which the devices were subjected to negative/positive bias, temperature, and illumination stresses, which are known to cause the most stress to oxide semiconductor TFTs. We also report on the key factors that affect the sub-gap defect states, and suggest a possible origin of the current degradation observed with an AC drive. Circuit designers should apply a similar discovery and analysis method to ensure the reliable design of integrated circuits with oxide semiconductor devices, such as the gate driver circuits used in display devices.

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Highly Stable AlInZnSnO and InZnO Double-Layer Oxide Thin-Film Transistors With Mobility Over 50 $\text{cm}^{2}/\text{V} \cdot \text{s}$ for High-Speed Operation

Yang

Choi

Cho

et al. 2018

IEEE Electron Device Lett.

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Sung Haeng Cho

Computational discovery of p-type transparent oxide semiconductors using hydrogen descriptor

Effect of hydrogen diffusion in an In–Ga–Zn–O thin film transistor with an aluminum oxide gate insulator on its electrical properties

Spectroscopy and energy disposal dynamics of phthalocyanine–Ar (n=1,2) complexes generated by hyperthermal pulsed nozzle source

Impact of transient currents caused by alternating drain stress in oxide semiconductors

Highly Stable AlInZnSnO and InZnO Double-Layer Oxide Thin-Film Transistors With Mobility Over 50 $\text{cm}^{2}/\text{V} \cdot \text{s}$ for High-Speed Operation

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