Sodium adsorption on nanometer-thick TiO2 channel thin-film transistors for enhanced drain currents

Journal of Vacuum Science & Technology B Pub Date : 2024-03-01 DOI:10.1116/6.0003217

Ryo Miyazawa, Haruto Suzuki, Hibiki Takeda, M. Miura, B. Ahmmad, Fumihiko Hirose

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Abstract

Sodium adsorption on nanometer-thick-TiO2-channel thin-film transistors (TFTs) are examined for enhancing the drain current. In the TFTs, the channel thickness of TiO2 is set as thin as ∼16 nm. The TiO2 film is deposited by atomic layer deposition using plasma excited humified Ar, followed by crystallization into the anatase phase by thermal annealing at 500 °C in air. The gate oxide is a 300 nm thick SiO2 film, which is grown on a highly doped n+ Si substrate. The n+ Si substrate is used as the gate electrode. The drain and source electrodes of Ti are deposited by an electron beam evaporation at room temperature. The TiO2 channel is covered with multiple layers of aluminum silicate and SiO2 films to enhance the Na sorptivity. The multiple films consist of combinations of 1 nm thick SiO2 and 0.16 nm thick aluminum silicate. The channel length and width are 60 and 1000 μm, respectively. The TFT without the Na adsorption exhibits a field effect mobility of ∼0.5 cm2/V s, where the drain current is recorded around 30 μA with a gate voltage of 10 V. With immersion of the TFT in a 10 mM NaCl solution, the drain current is enhanced to the order of mA. The simulation with an equivalent circuit with source and drain resistances suggests that the field effect mobility is enhanced to ∼30 cm2/V s with the adsorption of Na. In this paper, we discuss the operation mechanism of the Na adsorbed TiO2 TFT and its applicability as TFT-based high current switch devices and sensors.

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在纳米厚的 TiO2 沟道薄膜晶体管上吸附钠以增强漏极电流

研究了钠在纳米厚二氧化钛沟道薄膜晶体管（TFT）上的吸附作用，以提高漏极电流。在 TFT 中，TiO2 沟道的厚度设定为 16 纳米。TiO2 薄膜是通过使用等离子体激发的腐化氩气进行原子层沉积，然后在空气中以 500 °C 的温度热退火结晶成锐钛相。栅极氧化物是在高掺杂 n+ 硅衬底上生长的 300 nm 厚的 SiO2 薄膜。n+ 硅衬底用作栅极。漏极和源极的钛是在室温下通过电子束蒸发沉积的。TiO2 沟道上覆盖了多层硅酸铝和 SiO2 薄膜，以提高 Na 吸水率。多层薄膜由 1 纳米厚的二氧化硅和 0.16 纳米厚的硅酸铝组合而成。沟道长度和宽度分别为 60 微米和 1000 微米。未吸附 Na 的 TFT 的场效应迁移率为 0.5 cm2/V s，在栅极电压为 10 V 时，漏极电流约为 30 μA。将 TFT 浸入 10 mM NaCl 溶液后，漏极电流增强到 mA 量级。利用具有源极和漏极电阻的等效电路进行的模拟表明，在吸附 Na 后，场效应迁移率提高到 30 cm2/V s。本文讨论了 Na 吸附 TiO2 TFT 的运行机制及其作为基于 TFT 的大电流开关器件和传感器的适用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Vacuum Science & Technology B

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