High mobility InGaZnO thin film transistor using narrow-bandgap titanium-oxide semiconductor as channel capping layer

72nd Device Research Conference Pub Date : 2014-06-22 DOI:10.1109/DRC.2014.6872320

H. Hsu, P. Chiou, Y. Chiu, S. Yen, C. Chang, C. H. Cheng

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Abstract

Metal-oxide InGaZnO thin-film transistors (IGZO TFTs) have received substantial attention as potential substitutes for amorphous Si and/or polycrystalline Si in active-matrix liquid-crystal displays, active-matrix organic light emitted diodes (AMOLEDs), and three-dimensional (3D) display applications [1]-[2]. It is well known that the multi-alloy IGZO channel plays an important role in device characteristics such as subthreshold swing (SS) and field-effect mobility (μFE). Although the high-K gate dielectrics to lower operating voltage and threshold voltage (VT) of TFT devices have demonstrated [3]-[5], these critical issues on transfer characteristics still need to be overcome. The large SS and low μFE prevent them from being applied in fast-switching and high-resolution displays. In this paper, we demonstrate high mobility IGZO TFT with titanium oxide (TiOx) channel capping layer. Large μfe of 66 cm2/Vs and low SS of 79 mV/dec were achieved using narrow-bandgap TiOx (Eg~ 3.1eV) [6] with optimized 5-nm thickness. The similar bandgap and conduction band offset to those of IGZO are favorable to obtain a low resistance ohmic contact between amorphous IGZO and Al contact metals.

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采用窄带隙氧化钛半导体作为沟道封盖层的高迁移率InGaZnO薄膜晶体管

金属氧化物InGaZnO薄膜晶体管(IGZO TFTs)作为有源矩阵液晶显示器、有源矩阵有机发光二极管(amoled)和三维(3D)显示应用中非晶硅和/或多晶硅的潜在替代品受到了广泛关注[1]-[2]。众所周知，多合金IGZO通道对器件的亚阈值摆幅(SS)和场效应迁移率(μFE)等特性起着重要的作用。虽然高k栅极电介质降低TFT器件的工作电压和阈值电压(VT)的效果已经得到了证明[3]-[5]，但这些传输特性上的关键问题仍然需要克服。大SS和低μFE阻碍了它们在快速切换和高分辨率显示中的应用。在本文中，我们展示了具有氧化钛(TiOx)通道封盖层的高迁移率IGZO TFT。采用优化厚度为5 nm的窄带隙TiOx (Eg~ 3.1eV)[6]，获得了66 cm2/Vs的大μfe和79 mV/dec的低SS。与IGZO相似的带隙和导带偏置有利于获得非晶IGZO与Al接触金属之间的低电阻欧姆接触。

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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72nd Device Research Conference

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