材料科学
钝化
薄膜晶体管
氧化物
光电子学
晶体管
有机发光二极管
纳米技术
图层(电子)
电气工程
冶金
工程类
电压
作者
Yen‐Hung Lin,Seitkhan, A,Hastas, N,Faber, H,N. A. Hastas,Pliatsikas, N,Qiang Zhang,Xixiang Zhang,Khim, D,Anthopoulos, T,Bradley, D,Patsalas, P,Tsetseris, L,Huang, W
出处
期刊:University of Oxford - Oxford University Research Archive (ORA)
日期:2019-12-16
被引量:61
标识
DOI:10.1038/s41928-019-0342-y
摘要
Metal oxide thin-film transistors are increasingly used in the driving backplanes of organic light-emitting diode displays. Commercial devices currently rely on metal oxides processed via physical vapour deposition methods, but the use of solution-based processes could provide a simpler, higher-throughput approach that would be more cost effective. However, creating oxide transistors with high carrier mobility and bias-stable operation using such processes has proved challenging. Here we show that transistors with high electron mobility (50 cm2 V−1 s−1) and operational stability can be fabricated from solution-processed multilayer channels composed of ultrathin layers of indium oxide, zinc oxide nanoparticles, ozone-treated polystyrene and compact zinc oxide. Insertion of the ozone-treated polystyrene interlayer passivates electron traps in the channel and reduces bias-induced instability during continuous transistor operation over a period of 24 h and under a high electric-field flux density (2.1 × 10−6 C cm−2). Furthermore, incorporation of the pre-synthesized aluminium-doped zinc oxide nanoparticles enables controlled n-type doping of the hybrid channels, providing additional control over the operating characteristics of the transistors.
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