应用于基于纳米晶体的红外传感的亥姆霍兹谐振器。

Helmholtz Resonator Applied to Nanocrystal-Based Infrared Sensing.

作者信息

Abadie Claire, Paggi Laura, Fabas Alice, Khalili Adrien, Dang Tung Huu, Dabard Corentin, Cavallo Mariarosa, Alchaar Rodolphe, Zhang Huichen, Prado Yoann, Bardou Nathalie, Dupuis Christophe, Xu Xiang Zhen, Ithurria Sandrine, Pierucci Debora, Utterback James K, Fix Baptiste, Vincent Grégory, Bouchon Patrick, Lhuillier Emmanuel

机构信息

DOTA, ONERA, Université Paris Saclay, F-91123 Palaiseau, France.

CNRS, Institut des NanoSciences de Paris, Sorbonne Université, 4 place jussieu, F-75005 Paris, France.

出版信息

Nano Lett. 2022 Nov 9;22(21):8779-8785. doi: 10.1021/acs.nanolett.2c02769. Epub 2022 Oct 3.

DOI:10.1021/acs.nanolett.2c02769

PMID:36190814

Abstract

While the integration of nanocrystals as an active medium for optoelectronic devices progresses, light management strategies are becoming required. Over recent years, several photonic structures (plasmons, cavities, mirrors, etc.) have been coupled to nanocrystal films to shape the absorption spectrum, tune the directionality, and so on. Here, we explore a photonic equivalent of the acoustic Helmholtz resonator and propose a design that can easily be fabricated. This geometry combines a strong electromagnetic field magnification and a narrow channel width compatible with efficient charge conduction despite hopping conduction. At 80 K, the device reaches a responsivity above 1 A·W and a detectivity above 10 Jones (3 μm cutoff) while offering a significantly faster time-response than vertical geometry diodes.

摘要

随着将纳米晶体用作光电器件有源介质的集成技术不断发展，光管理策略变得愈发必要。近年来，几种光子结构（等离子体激元、腔、镜等）已与纳米晶体薄膜耦合，以塑造吸收光谱、调整方向性等。在此，我们探索声学亥姆霍兹共振器的光子等效物，并提出一种易于制造的设计。这种几何结构结合了强大的电磁场放大作用和与高效电荷传导兼容的窄通道宽度，尽管存在跳跃传导。在80 K时，该器件的响应度高于1 A·W，探测率高于10琼斯（截止波长3μm），同时提供比垂直几何结构二极管快得多的时间响应。