材料科学
接口(物质)
理想(伦理)
电流(流体)
晶体管
光电子学
场效应晶体管
电压
领域(数学)
工程物理
电气工程
哲学
数学
认识论
毛细管数
毛细管作用
纯数学
复合材料
工程类
作者
Jianzhou Ren,Bokun Rong,Lei Zheng,Yongxu Hu,Yuchan Wang,Zhongwu Wang,Xiaosong Chen,Kailiang Zhang,Liqiang Li,Wenping Hu
标识
DOI:10.1002/adfm.202412472
摘要
Abstract The key roles of electrode/semiconductor and semiconductor/dielectric interfaces play in the ideality of organic field‐effect transistors (OFETs) by traditional device preparation technologies are not yet fully understood, which severely limits progress in the design of molecules, the understanding of transport mechanisms, and the circuit applications of OFETs. Herein, at a quantitative level, the origin of nonideal current–voltage ( I– V ) curves and possibly overestimated mobility in single‐crystal OFETs is revealed, including contact resistance ( R c ), charge trapping, and scattering at interfaces of devices. Impressively, an efficient interface collaborative strategy, which consists of transferred “doped” electrodes with tunable contact “doping” localized regions at the source‐drain contacts and polymer‐modified SiO 2 with suitable surface polarity ( γ s p ) is further demonstrated that have great advantages in the construction of ideal high mobility devices. Also, an interesting double‐edged sword effect of γ s p of dielectric on the ideality of OFETs is observed. The dielectric with a lower γ s p can result in higher mobility, while too low γ s p would degrade the device ideality due to significant effect of charge scattering. The findings not only provide new perspectives and strategies to construct ideal OFETs but also offer useful guidance to correctly evaluate organic semiconductor materials.
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