材料科学
晶体管
薄膜晶体管
光电子学
调制(音乐)
无定形固体
氧化物
阈下传导
电子迁移率
阈值电压
电压
纳米技术
电气工程
物理
化学
图层(电子)
结晶学
工程类
声学
冶金
作者
Nikhil Tiwale,Ashwanth Subramanian,Zhongwei Dai,Sayantani Sikder,Jerzy T. Sadowski,Chang‐Yong Nam
标识
DOI:10.1038/s43246-020-00096-w
摘要
Abstract Recently, ultrathin metal-oxide thin film transistors (TFTs) have shown very high on-off ratio and ultra-sharp subthreshold swing, making them promising candidates for applications beyond conventional large-area electronics. While the on-off operation in typical TFTs results primarily from the modulation of charge carrier density by gate voltage, the high on-off ratio in ultrathin oxide TFTs can be associated with a large carrier mobility modulation, whose origin remains unknown. We investigate 3.5 nm-thick TiO x -based ultrathin TFTs exhibiting on-off ratio of ~10 6 , predominantly driven by ~6-decade gate-induced mobility modulation. The power law behavior of the mobility features two regimes, with a very high exponent at low gate voltages, unprecedented for oxide TFTs. We find that this phenomenon is well explained by the presence of high-density tail states near the conduction band edge, which supports carrier transport via variable range hopping. The observed two-exponent regimes reflect the bi-exponential distribution of the density of band-tail states. This improved understanding would be significant in fabricating high-performance ultrathin oxide devices.
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