Enhanced luminescence excitation via efficient optical energy transfer (Presentation Recording)

R. Aad, K. Nomenyo, B. Bercu, C. Couteau, V. Sallet, D. Rogers, M. Molinari, G. Lerondel
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Abstract

Luminescent nanoscale materials (LNMs) have received widespread interest in sensing and lighting applications due to their enhanced emissive properties. For sensing applications, LNMs offer improved sensitivity and fast response time which allow for lower limits of detection. Meanwhile, for lighting applications, LNMs, such as quantum dots, offer an improved internal quantum efficiency and controlled color rendering which allow for better lighting performances. Nevertheless, due to their nanometric dimensions, nanoscale materials suffer from extremely weak luminescence excitation (i.e. optical absorption) limiting their luminescence intensity, which in turn results in a downgrade in the limits of detection and external quantum efficiencies. Therefore, enhancing the luminescence excitation is a major issue for sensing and lighting applications. In this work, we report on a novel photonic approach to increase the luminescence excitation of nanoscale materials. Efficient luminescence excitation increase is achieved via a gain-assisted waveguided energy transfer (G-WET). The G-WET concept consists on placing nanoscale materials atop of a waveguiding active (i.e. luminescent) layer with optical gain. Efficient energy transfer is thus achieved by exciting the nanoscale material via the tail of the waveguided mode of the active layer emission. The G-WET concept is demonstrated on both a nanothin layer of fluorescent sensitive polymer and on CdSe/ZnS quantum dots coated on ZnO thin film, experimentally proving up to an 8-fold increase in the fluorescence of the polymer and a 3-fold increase in the luminescence of the CdSe/ZnS depending of the active layer emission regime (stimulated vs spontaneous emission). Furthermore, we will discuss on the extended G-WET concept which consists on coating nanoscale materials on a nanostructured active layer. The nanostructured active layer offers the necessary photonic modulation and a high specific surface which can presumably lead to a more efficient G-WET concept. Finally, the efficiency as well as the observation conditions of the GWET will be discussed and compared with more conventional charge transfer or dipole-dipole energy transfer.
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通过有效的光能转移增强发光激发(演示记录)
发光纳米材料由于其增强的发射特性,在传感和照明领域得到了广泛的关注。对于传感应用,lnm提供更高的灵敏度和更快的响应时间,从而允许更低的检测极限。同时,在照明应用方面,量子点等lnm提供了改进的内部量子效率和可控的显色性,从而实现了更好的照明性能。然而,由于其纳米尺寸,纳米级材料的发光激发(即光吸收)非常弱,限制了其发光强度,这反过来导致检测极限和外部量子效率的降低。因此,增强发光激发是传感和照明应用的主要问题。在这项工作中,我们报告了一种新的光子方法来增加纳米级材料的发光激发。通过增益辅助波导能量转移(G-WET)实现了有效的发光激发增加。G-WET概念包括将纳米级材料放置在具有光学增益的波导有源(即发光)层之上。通过有源层发射的波导模式尾部激发纳米级材料,实现了有效的能量传递。G-WET概念在荧光敏感聚合物的纳米薄层和涂覆在ZnO薄膜上的CdSe/ZnS量子点上进行了演示,实验证明,根据活性层发射机制(受激发射与自发发射),聚合物的荧光增加了8倍,CdSe/ZnS的发光增加了3倍。此外,我们将讨论扩展的G-WET概念,包括在纳米结构的活性层上涂覆纳米级材料。纳米结构的有源层提供了必要的光子调制和高比表面,这可能会导致更有效的G-WET概念。最后,讨论了GWET的效率和观测条件,并与更常规的电荷转移或偶极-偶极能量转移进行了比较。
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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