Abstract
As a powerful tool for studying molecular dynamics in bioscience, single-molecule fluorescence detection provides dynamical information buried in ensemble experiments. Fluorescence in the near-infrared (NIR) is particularly useful because it offers higher signal-to-noise ratio and increased penetration depth in tissue compared with visible fluorescence. The low quantum yield of most NIR fluorophores, however, makes the detection of single-molecule fluorescence difficult. Here, we use asymmetric plasmonic nano-antenna to enhance the fluorescence intensity of AIEE1000, a typical NIR dye, by a factor up to 405. The asymmetric nano-antenna achieve such an enhancement mainly by increasing the quantum yield (to ~80%) rather than the local field, which degrades the molecules’ photostability. Our coupled-mode-theory analysis reveals that the enhancements stem from resonance-matching between antenna and molecule and, more importantly, from optimizing the coupling between the near- and far-field modes with designer asymmetric structures. Our work provides a universal scheme for engineering single-molecule fluorescence in the near-infrared regime.
Highlights
1234567890():,; 1234567890():,; 1234567890():,; 1234567890():,; Introduction Single-molecule fluorescence detection (SMFD) is able to probe, one molecule at a time, dynamical processes that are crucial for understanding functional mechanisms in biosystems[1,2,3]
The plasmonic nano-antenna generally enhances the fluorescence of a nearby molecule by enhancing the excitation rate and the quantum yield of the molecule
The total fluorescence enhancement FE is the product of the two enhancement factors, FE = Fexc · Fem, where Fexc denotes the enhancement on excitation rate while Fem denotes the enhancement on quantum yield of the molecule
Summary
Single-molecule fluorescence detection (SMFD) is able to probe, one molecule at a time, dynamical processes that are crucial for understanding functional mechanisms in biosystems[1,2,3]. Plasmonic nanostructures are capable of converting localized electromagnetic energy into free radiation and vice versa[6]. This capability makes them efficient nanoantennas for modulating molecular fluorescence[7,8,9,10,11,12]. The plasmonic nano-antenna generally enhances the fluorescence of a nearby molecule by enhancing the excitation rate and the quantum yield of the molecule. The practice does not usually guarantee an optimized FE; to achieve large FE, it is imperative that both Fexc and Fem are optimized for a particular antenna design.
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