等离子体激光传感器(演示记录)

R. Ma, S. Ota, Yimin Li, Sui Yang, Xiang Zhang
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引用次数: 0

摘要

到目前为止,等离子体学最成功的应用可能是在传感领域,纳米尺度的局部场与被分析物的相互作用可以实现高灵敏度的实时检测,并且无需标记。然而,以前所有的设计都是基于被动激发的表面等离子体,其灵敏度本质上受到金属损耗引起的低质量因素的限制。最近从理论上提出,由于表面等离子体的放大,具有主动激发(增益增强)的表面等离子体传感器可以获得更高的灵敏度。在这里,我们通过实验证明了一种无金属损耗的有源等离子体传感器,该传感器在可见光衍射极限以下工作。损耗补偿导致对吸附分子超敏感的强而锐利的激光发射。我们验证了传感器在正常条件下检测空气中爆炸物的有效性,并达到了十亿分之一的检测极限,这是迄今为止报道的含有2,4-二硝基甲苯和硝酸铵的等离子体传感器的最低检测极限。2,4-二硝基甲苯、硝酸铵和硝基苯之间的选择性与其他最先进的爆炸物探测器不相上下。我们的研究结果表明,监测激光强度的变化是一种比监测波长位移更好的方法,波长位移被广泛用于被动表面等离子体传感器。因此,我们设想利用等离子体激光的纳米传感器可以成为安全筛查和生物分子诊断的重要工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Plasmonic laser sensors (Presentation Recording)
Perhaps the most successful application of plasmonics to date has been in sensing, where the interaction of a nanoscale localized field with analytes leads to high-sensitivity detection in real time and in a label-free fashion. However, all previous designs have been based on passively excited surface plasmons, in which sensitivity is intrinsically limited by the low quality factors induced by metal losses. It has recently been proposed theoretically that surface plasmon sensors with active excitation (gain-enhanced) can achieve much higher sensitivities due to the amplification of the surface plasmons. Here, we experimentally demonstrate an active plasmon sensor that is free of metal losses and operating deep below the diffraction limit for visible light. Loss compensation leads to an intense and sharp lasing emission that is ultrasensitive to adsorbed molecules. We validated the efficacy of our sensor to detect explosives in air under normal conditions and have achieved a sub-part-per-billion detection limit, the lowest reported to date for plasmonic sensors with 2,4-dinitrotoluene and ammonium nitrate. The selectivity between 2,4-dinitrotoluene, ammoniumnitrate and nitrobenzene is on a par with other state-of-the-art explosives detectors. Our results show that monitoring the change of the lasing intensity is a superior method than monitoring the wavelength shift, as is widely used in passive surface plasmon sensors. We therefore envisage that nanoscopic sensors that make use of plasmonic lasing could become an important tool in security screening and biomolecular diagnostics.
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