Quantum dot optofluidic lasers and their prospects for biochemical sensing

SPIE LASE Pub Date : 2016-04-22 DOI:10.1117/12.2214889

A. Kiraz, Qiushu Chen, M. Aas, A. Jonáš, Xudong Fan

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引用次数: 1

Abstract

We achieved four types of laser emissions with quantum dots (QDs) using the same high-Q-factor optofluidic ring resonator (OFRR) platform. In the first type, 2 μM QDs dissolved in toluene that filled the entire OFRR cavity volume were employed as the gain medium. The lasing threshold was 15-22 μJ/mm2. In the second type, 2 μM aqueous QDs were in bulk buffer solution that filled the entire OFRR cavity volume. The lasing threshold was 0.1 μJ/mm2, over 3 orders of magnitude lower than the state-of-the-art. In the third type, the aqueous QDs were immobilized as a single layer on the interface between the OFRR inner wall and buffer solution with a surface density as low as 3×109 − 1010cm−2. The lasing threshold of 60 μJ/mm2 was achieved. In the fourth type, we achieved optofluidic FRET lasing using aqueous QDs as FRET donors and Cy5 dye molecules as acceptors. We observed lasing from Cy5 emission band in QD-Cy5 pair when excited at QD absorption band, far away from Cy5 absorption maximum. We also report a comprehensive theoretical analysis of optofluidic FRET lasers that was performed based on a Fabry-Perot microcavity using a rate equation model. By comparing FRET lasingbased sensors with conventional sensors using FRET signals obtained by spontaneous fluorescence emission, we show that for optimal pump fluence and FRET pair concentration, FRET lasing can lead to more than 20-fold enhancement in detection sensitivities of conformation changes for linker lengths in the Förster radius range.

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量子点光流激光器及其在生化传感中的应用前景

我们使用相同的高q因子光流体环形谐振器(OFRR)平台实现了四种类型的量子点激光发射。第一种是用溶解在甲苯中的2 μM量子点作为增益介质，填充整个OFRR腔体体积。激光阈值为15 ~ 22 μJ/mm2。在第二种类型中，2 μM的水性量子点位于填充整个OFRR空腔体积的散装缓冲溶液中。激光阈值为0.1 μJ/mm2，比现有激光阈值低3个数量级以上。在第三种类型中，水性量子点作为单层固定在OFRR内壁和缓冲溶液之间的界面上，表面密度低至3×109−1010cm−2。激光阈值为60 μJ/mm2。在第四种类型中，我们使用水性量子点作为FRET供体和Cy5染料分子作为受体实现了光流体FRET激光。当QD-Cy5对在QD吸收带激发时，可以观察到Cy5发射带的激光，远离Cy5吸收最大值。我们还报道了基于Fabry-Perot微腔使用速率方程模型对光流体FRET激光器进行的全面理论分析。通过比较基于FRET激光的传感器与使用自发荧光发射获得FRET信号的传统传感器，我们发现，对于最佳泵浦流量和FRET对浓度，FRET激光可以导致在Förster半径范围内的连接体长度构象变化的检测灵敏度提高20倍以上。

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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