Real-time monitoring of fast gas dynamics with a single-molecule resolution by frequency-comb-referenced plasmonic phase spectroscopy

IF 15.7 Q1 OPTICS PhotoniX Pub Date : 2024-08-13 DOI:10.1186/s43074-024-00140-9
Duy-Anh Nguyen, Dae Hee Kim, Geon Ho Lee, San Kim, Dong-Chel Shin, Jongkyoon Park, Hak-Jong Choi, Seung-Woo Kim, Seungchul Kim, Young-Jin Kim
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Abstract

Surface plasmon resonance (SPR) sensors are based on photon-excited surface charge density oscillations confined at metal-dielectric interfaces, which makes them highly sensitive to biological or chemical molecular bindings to functional metallic surfaces. Metal nanostructures further concentrate surface plasmons into a smaller area than the diffraction limit, thus strengthening photon-sample interactions. However, plasmonic sensors based on intensity detection provide limited resolution with long acquisition time owing to their high vulnerability to environmental and instrumental noises. Here, we demonstrate fast and precise detection of noble gas dynamics at single molecular resolution via frequency-comb-referenced plasmonic phase spectroscopy. The photon-sample interaction was enhanced by a factor of 3,852 than the physical sample thickness owing to plasmon resonance and thermophoresis-assisted optical confinement effects. By utilizing a sharp plasmonic phase slope and a high heterodyne information carrier, a small atomic-density modulation was clearly resolved at 5 Hz with a resolution of 0.06 Ar atoms per nano-hole (in 10–11 RIU) in Allan deviation at 0.2 s; a faster motion up to 200 Hz was clearly resolved. This fast and precise sensing technique can enable the in-depth analysis of fast fluid dynamics with the utmost resolution for a better understanding of biomedical, chemical, and physical events and interactions.

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利用频率-梳状参比等离子体相位光谱以单分子分辨率实时监测快速气体动力学
表面等离子体共振(SPR)传感器基于局限在金属-介电界面上的光子激发表面电荷密度振荡,这使其对功能金属表面的生物或化学分子结合高度敏感。金属纳米结构进一步将表面质子集中到比衍射极限更小的区域,从而加强了光子与样品之间的相互作用。然而,基于强度检测的质子传感器由于极易受到环境和仪器噪声的影响,因此分辨率有限,采集时间较长。在这里,我们展示了通过频率-梳状参比的等离子体相位光谱在单分子分辨率下快速、精确地检测惰性气体的动态。由于等离子体共振和热泳辅助光学约束效应,光子与样品的相互作用比物理样品厚度增强了 3,852 倍。通过利用尖锐的等离子体相位斜率和高外差信息载体,在 5 Hz 的频率下清晰地分辨出了小原子密度调制,在 0.2 s 的时间内,每个纳米孔的阿伦偏差分辨率为 0.06 Ar 原子(10-11 RIU);在 200 Hz 的频率下,也能清晰地分辨出更快的运动。这种快速而精确的传感技术能够以最高的分辨率对快速流体动力学进行深入分析,从而更好地了解生物医学、化学和物理事件及相互作用。
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来源期刊
CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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