Laser-induced fluorescence of coumarin derivatives in aqueous solution: Photochemical aspects for single molecule detection

C. Eggeling, L. Brand, C. Seidel
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引用次数: 39

Abstract

The efficiency of detecting a single fluorescent coumarin dye molecule in aqueous solution by one-photon excitation (OPE) at 350 nm as well as by coherent two-photon excitation (TPE) at 700 nm is studied. The photostability, which is crucial for single molecule detection (SMD), is determined at a low irradiance for various coumarin derivatives using a ‘cell-bleaching’ method. The yields of photobleaching for these coumarins in aqueous solution are in the order of 10−3 to 10−4. Thus, most of the dyes are sufficiently stable to allow SMD. However, for SMD in a fluorescence microscope a high quasi-CW irradiance (at least 104 W cm−2) is necessary for efficient OPE by a pulsed, frequency doubled titanium:sapphire laser. Detailed investigations on the dye Coumarin-120 using fluorescence correlation spectroscopy (FCS), different repetition rates of the laser and transient absorption spectroscopy (TRABS) gave clear evidence that OPE at a high irradiance results in two-step photolysis via the first electronic excited singlet and triplet state, S1 and T1, producing dye radical ions and solvated electrons. Hence, this additional photobleaching pathway limits the applicable irradiance for OPE. Using coherent TPE for single molecule detection, saturation of the fluorescence was observed for a high quasi-CW irradiance (108 W cm−2), which may also be caused by photobleaching. Furthermore, TPE is deteriorated by other competing nonlinear processes (e.g. continuum generation in the solvent), which only occur above a threshold irradiance (7 × 107 W cm−2). Nevertheless, TPE allows an efficient detection of single Coumarin-120 molecules in water. Using a maximum likelihood estimator, we are also able to identify single dye molecules via their characteristic fluorescence lifetime of 4.8 ± 1.2 ns.
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水溶液中香豆素衍生物的激光诱导荧光:单分子检测的光化学方面
研究了350 nm单光子激发(OPE)和700 nm相干双光子激发(TPE)在水溶液中检测单个荧光香豆素染料分子的效率。光稳定性对单分子检测(SMD)至关重要,它是使用“细胞漂白”方法在低辐照度下测定各种香豆素衍生物的。这些香豆素在水溶液中光漂白的产率为10−3 ~ 10−4。因此,大多数染料都足够稳定,可以进行SMD。然而,对于荧光显微镜下的SMD,需要高准连续波辐照度(至少104 W cm−2)才能通过脉冲倍频钛:蓝宝石激光器实现有效的OPE。利用荧光相关光谱(FCS)、不同激光重复率和瞬态吸收光谱(TRABS)对染料香豆素-120进行了详细的研究,清楚地表明,在高辐照度下,OPE通过第一电子激发单重态和三重态S1和T1进行了两步光解,产生染料自由基离子和溶剂化电子。因此,这种额外的光漂白途径限制了OPE的适用辐照度。使用相干TPE进行单分子检测,在高准连续波辐照度(108 W cm−2)下观察到荧光饱和,这也可能是由光漂白引起的。此外,TPE还会受到其他非线性过程的影响(例如溶剂中连续统的产生),这些过程仅发生在阈值辐照度(7 × 107 W cm−2)以上。然而,TPE可以有效地检测水中单个香豆素-120分子。使用最大似然估计器,我们还能够通过单个染料分子的特征荧光寿命(4.8±1.2 ns)来识别它们。
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