Youyan Lu, Liyun Liu, Ruoqian Gao, Ying Xiong, Peiqing Sun, Zhanghao Wu, Kai Wu, Tong Yu, Kai Zhang, Cheng Zhang, Tarik Bourouina, Xiaofeng Li, Xiaoyi Liu
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引用次数: 0
Abstract
Pyroelectric (PE) detection technologies have attracted extensive attention due to the cooling-free, bias-free, and broadband properties. However, the PE signals are generated by the continuous energy conversion processes from light, heat, to electricity, normally leading to very slow response speeds. Herein, we design and fabricate a PE detector which shows extremely fast response in near-infrared (NIR) band by combining with the inhomogeneous plasmonic metasurface. The plasmonic effect dramatically accelerates the light-heat conversion process, unprecedentedly improving the NIR response speed by 2-4 orders of magnitude to 22 μs, faster than any reported infrared (IR) PE detector. We also innovatively introduce the concept of time resolution into the field of PE detection, which represents the detector's ability to distinguish multiple fast-moving targets. Furthermore, the spatially inhomogeneous design overcomes the traditional narrowband constraint of plasmonic systems and thus ensures a wideband response from visible to NIR. This study provides a promising approach to develop next-generation IR PE detectors with ultrafast and broadband responses.
热释电 (PE) 检测技术因其无冷却、无偏差和宽带特性而受到广泛关注。然而,热释电信号是通过从光、热到电的连续能量转换过程产生的,通常导致响应速度非常缓慢。在此,我们设计并制造了一种 PE 探测器,通过与非均匀质子元表面相结合,该探测器在近红外(NIR)波段显示出极快的响应速度。质子效应显著加速了光热转换过程,前所未有地将近红外响应速度提高了 2-4 个数量级,达到 22 μs,比任何已报道的红外 PE 探测器都要快。我们还在 PE 检测领域创新性地引入了时间分辨率的概念,它代表了检测器分辨多个快速移动目标的能力。此外,空间不均匀设计克服了传统等离子系统的窄带限制,从而确保了从可见光到近红外的宽带响应。这项研究为开发具有超快和宽带响应的下一代红外 PE 探测器提供了一种前景广阔的方法。
期刊介绍:
Light: Science & Applications is an open-access, fully peer-reviewed publication.It publishes high-quality optics and photonics research globally, covering fundamental research and important issues in engineering and applied sciences related to optics and photonics.