Alex W. Lee scite author profile

Alex W. Lee

2Publications

73Citation Statements Received

91Citation Statements Given

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Affiliations

Jacobs (United States), University of California, San Diego

Publications

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Hydrogen-Defect Termination in SnO for p-Channel TFTs

Lee

Dong

Matsuzaki

et al. 2020

ACS Appl. Electron. Mater.

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Developing high-performance p-channel oxide thin-film transistor (TFT) and practical oxide TFT-based complementary circuits is the most persistent challenge for oxide electronics and a major hurdle for future oxide device technology to overcome. Tin monoxide, SnO, is known as one of the promising candidates for an active layer of p-channel oxide TFT, owing to its reasonably high hole carrier mobility (over 1 cm2 V–1 s–1) and low-cost processability. However, high-density subgap defect spoils its high potential for electronic devices and hinders the development of SnO-based high-performance p-channel oxide TFTs. Here, we present hydrogen-defect termination for SnO to improve the device performance of p-channel oxide TFT. Thermal annealing in hydrogen ambient using a pure NH3 at 360 °C offers good TFT characteristics with the saturation mobilities of ∼1.4–1.8 cm2 V–1 s–1 and an on-to-off current ratio of ∼105 because of the hydrogen termination of the subgap hole trap originating from the oxygen vacancy. A complementary inverter comprising p-channel SnO and n-channel a-IGZO TFTs was demonstrated with a maximum voltage gain of ∼50. This present achievement is an important step toward building low-cost next-generation oxide electronics.

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Switching Mechanism behind the Device Operation Mode in SnO‐TFT

Lee

Zhang

Huang

et al. 2020

Adv Elect Materials

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performances, including high TFT mobility (≈10 cm 2 V −1 s −1), low operation voltage (≈3 V), and low off-current characteristics as well as excellent mechanical flexibility and low-cost processability. [4] Therefore, n-channel a-IGZO-TFT is successfully commercialized in the market and widely used as a TFT backplane in the state-of-art active-matrix flat panel display such as large-sized high-resolution organic light-emitting diode and low-power consumption active-matrix liquid crystal display. [5-7] The next major challenge faced in oxide semiconductor technology is to develop complementary metal-oxide semiconductor (CMOS) inverter circuits for future ubiquitous device applications. So far, several CMOS inverters based on oxide-TFTs have been demonstrated with n-type oxide a-IGZO and p-type oxides such as SnO, Cu 2 O, and organic semiconductors. [8-10] However, different fabrication process involved in n-and p-type materials results in complicated circuit design and integration, leading to the production of the impractical circuit. [11]

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Alex W. Lee

Hydrogen-Defect Termination in SnO for p-Channel TFTs

Switching Mechanism behind the Device Operation Mode in SnO‐TFT

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