State Key Laboratory for Infrared Physics, Shanghai Institute of Technical Physics, Chinese Academy of Sciences, 500 Yutian Road, Shanghai 200083, China.
Nanoscale. 2018 Mar 29;10(13):5852-5858. doi: 10.1039/C7NR09545G.
The present work reports on a graphene-like material that is promising for photodetection applications due to its high optical absorption and layer-dependent properties. To date, only narrowband photodetectors have been realized; therefore, extending the working wavelength is becoming more imperative for applications such as high-contrast imaging and remote sensing. In this work, we developed a novel detection technique that provides enhanced performance across the infrared and terahertz bands by using an antenna-assisted top-gated black phosphorus phototransistor. By using the proposed sophisticated design, the adverse effect due to the back-gate that is generally employed for a long-wavelength photon coupling can be eliminated. Moreover, the antenna-assisted near-field and dark current can be further tailored electromagnetically and electrostatically by employing a gate finger, thus resulting in improved detection efficiency. Various detection mechanisms such as thermoelectric, bolometric, and electron-hole generation are differentiated on the basis of the device geometry and incident wavelength. The proposed photodetector demonstrated superior performance-excellent sensitivity of more than 10 V W-1, a noise equivalent power value of less than 0.1 nW Hz-0.5, and a fast response time across disparate wavebands. Thus, the photodetector can satisfy diverse application requirements.
本工作报道了一种类石墨烯材料,由于其高光吸收和层依赖性特性,有望用于光电探测应用。迄今为止,仅实现了窄带光电探测器;因此,对于高对比度成像和遥感等应用,扩展工作波长变得更加迫切。在这项工作中,我们开发了一种新颖的检测技术,通过使用天线辅助顶栅黑磷光电晶体管,在红外和太赫兹波段提供了增强的性能。通过使用所提出的复杂设计,可以消除通常用于长波长光子耦合的背栅的不利影响。此外,通过采用栅指,可以进一步电磁和静电调整天线辅助的近场和暗电流,从而提高检测效率。基于器件几何形状和入射波长,可以区分各种检测机制,如热电、量热和电子-空穴产生。所提出的光电探测器表现出卓越的性能-超过 10 V W-1 的超高灵敏度、小于 0.1 nW Hz-0.5 的噪声等效功率值以及在不同波段的快速响应时间。因此,该光电探测器可以满足各种应用需求。