Centre for Graphene Science, College of Engineering, Mathematics and Physical Sciences, University of Exeter, Exeter, EX4 4QF, UK.
INESC MN and IN, Rua Alves Redol No. 9, 1000-029, Lisboa, Portugal.
Adv Mater. 2017 Nov;29(41). doi: 10.1002/adma.201702993. Epub 2017 Sep 25.
Atomically thin materials such as graphene are uniquely responsive to charge transfer from adjacent materials, making them ideal charge-transport layers in phototransistor devices. Effective implementation of organic semiconductors as a photoactive layer would open up a multitude of applications in biomimetic circuitry and ultra-broadband imaging but polycrystalline and amorphous thin films have shown inferior performance compared to inorganic semiconductors. Here, the long-range order in rubrene single crystals is utilized to engineer organic-semiconductor-graphene phototransistors surpassing previously reported photogating efficiencies by one order of magnitude. Phototransistors based upon these interfaces are spectrally selective to visible wavelengths and, through photoconductive gain mechanisms, achieve responsivity as large as 10 A W and a detectivity of 9 × 10 Jones at room temperature. These findings point toward implementing low-cost, flexible materials for amplified imaging at ultralow light levels.
原子层厚的材料(如石墨烯)对来自相邻材料的电荷转移具有独特的响应能力,使其成为光电晶体管器件中理想的电荷传输层。有效实施有机半导体作为光活性层将为仿生电路和超宽带成像开辟众多应用,但与无机半导体相比,多晶和非晶薄膜的性能较差。在这里,利用并五苯单晶的长程有序来设计有机半导体-石墨烯光电晶体管,其光电门效率超过了先前报道的一个数量级。基于这些界面的光电晶体管对可见光波长具有光谱选择性,并且通过光电导增益机制,在室温下实现高达 10 A W 的响应度和 9×10 琼斯的探测率。这些发现为在超低光水平下实现低成本、灵活的放大成像材料指明了方向。
