Schottky Infrared Detectors with Optically Tunable Barriers Beyond the Internal Photoemission Limit

IF 33.2 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

The Innovation Pub Date : 2024-02-29 DOI:10.1016/j.xinn.2024.100600

Jintao Fu, Zhongmin Guo, Changbin Nie, Feiying Sun, Genglin Li, Shuanglong Feng, Xingzhan Wei

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Abstract

Internal photoemission is a prominent branch of the photoelectric effect and has emerged as a viable method for detecting photons with energies below the semiconductor bandgap. This breakthrough has played a significant role in accelerating the development of infrared imaging in one chip with state-of-the-art silicon techniques. However, the performance of these Schottky infrared detectors is currently hindered by the limit of internal photoemission; specifically, a low Schottky barrier height is inevitable for the detection of low-energy infrared photons. Herein, a distinct paradigm of Schottky infrared detectors is proposed to overcome the internal photoemission limit by introducing an optically tunable barrier. This device uses an infrared absorbing material-sensitized Schottky diode, assisted by the highly adjustable Fermi level of graphene, which subtly decouples the photon energy from the Schottky barrier height. Correspondingly, a broadband photoresponse spanning from ultraviolet to mid-wave infrared is achieved, with a high detectivity of 9.83×10 cm·Hz·W at 2700 nm and an excellent detectivity of 7.2×10 cm·Hz·W at room temperature under blackbody radiation. These results address a key challenge in internal photoemission, and hold great promise for the development of the Schottky infrared detector with high sensitivity and room-temperature operation.

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具有超越内部光发射极限的光学可调谐势垒的肖特基红外探测器

内部光发射是光电效应的一个重要分支，已成为探测能量低于半导体带隙的光子的一种可行方法。这一突破在利用最先进的硅技术加速发展单芯片红外成像技术方面发挥了重要作用。然而，这些肖特基红外探测器的性能目前受到内部光发射限制的阻碍；具体而言，低肖特基势垒高度是探测低能量红外光子所不可避免的。本文提出了一种独特的肖特基红外探测器范例，通过引入光学可调势垒来克服内部光发射限制。该器件使用红外吸收材料敏化的肖特基二极管，在石墨烯高度可调费米级的辅助下，巧妙地将光子能量与肖特基势垒高度解耦。相应地，实现了从紫外线到中波红外线的宽带光响应，在 2700 纳米波长下具有 9.83×10 cm-Hz-W 的高探测率，在室温黑体辐射下具有 7.2×10 cm-Hz-W 的出色探测率。这些结果解决了内部光发射的一个关键难题，为开发高灵敏度和室温工作的肖特基红外探测器带来了巨大希望。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

The Innovation MULTIDISCIPLINARY SCIENCES-

CiteScore

38.30

自引率

1.20%

发文量

134

审稿时长

6 weeks

期刊介绍： The Innovation is an interdisciplinary journal that aims to promote scientific application. It publishes cutting-edge research and high-quality reviews in various scientific disciplines, including physics, chemistry, materials, nanotechnology, biology, translational medicine, geoscience, and engineering. The journal adheres to the peer review and publishing standards of Cell Press journals. The Innovation is committed to serving scientists and the public. It aims to publish significant advances promptly and provides a transparent exchange platform. The journal also strives to efficiently promote the translation from scientific discovery to technological achievements and rapidly disseminate scientific findings worldwide. Indexed in the following databases, The Innovation has visibility in Scopus, Directory of Open Access Journals (DOAJ), Web of Science, Emerging Sources Citation Index (ESCI), PubMed Central, Compendex (previously Ei index), INSPEC, and CABI A&I.