Single-Molecule Sensitivity in Hot Microcavities in the Unstable Regime

ChemRxiv Pub Date : 2024-09-13 DOI:10.26434/chemrxiv-2024-xgtxg

Carlos A., Saavedra Salazar, Sushu, Wan, Nasrin, Asgari, Lisa-Maria, Needham, Randall, Goldsmith, Joel, Yuen-Zhou, Brendan, Cullinane, Julia, Rasch, Daniel, Sole-Barber, Michael, Reitz

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Abstract

Fiber Fabry-Perot microcavities (FFPCs) enhance light-matter interactions by localizing light in time and space. A new detection scheme exploiting photothermal non-linearities and Pound-Drever-Hall frequency locking enabled label-free detection of solution-phase single biomolecules with unprecedented sensitivity. Here, we deploy a combination of experiment and simulation to provide a quantitative mechanism for the observed single-molecule sensitivity and achieve quantitative agreement with experiment. Key elements of the mechanism include maintaining the FFPC in an unstable regime, allowing it to rapidly shift to hot and cold pho-tothermal equilibria upon perturbation. We show how Brownian molecular trajectories introducing resonance fluctuations less than one thousandth of a linewidth can produce selective and highly amplified responses as long as the perturbations exist in a specific and tunable frequency window termed the molecular velocity filter window. The model’s predictive capacity suggest it will be an im-portant tool to identify new regimes of single-molecule hydrodynamic profiling.

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不稳定区热微腔中的单分子灵敏度

光纤法布里-珀罗微腔（FFPCs）通过在时间和空间上定位光来增强光与物质的相互作用。一种利用光热非线性和 Pound-Drever-Hall 频率锁定的新型检测方案能够以前所未有的灵敏度对溶液相单一生物分子进行无标记检测。在这里，我们将实验与模拟相结合，为观察到的单分子灵敏度提供了一个定量机制，并与实验达成了定量一致。该机制的关键要素包括将 FFPC 保持在不稳定状态，使其在受到扰动时能迅速转变为热平衡和冷热平衡。我们展示了引入小于千分之一线宽共振波动的布朗分子轨迹如何产生选择性和高度放大的响应，只要扰动存在于特定的可调频率窗口（称为分子速度滤波窗口）中。该模型的预测能力表明，它将成为确定单分子流体力学剖析新体系的重要工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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