全内反射荧光显微镜用于研究纳米气泡动力学。

Total-internal-reflection-fluorescence microscopy for the study of nanobubble dynamics.

机构信息

Division of Physics and Applied Physics, School of Physical and Mathematical Sciences, Nanyang Technological University, Singapore 637371, Singapore.

出版信息

Phys Rev Lett. 2012 Oct 26;109(17):174501. doi: 10.1103/PhysRevLett.109.174501. Epub 2012 Oct 23.

DOI:10.1103/PhysRevLett.109.174501

PMID:23215193

Abstract

Nanobubbles can be observed with optical microscopy using the total-internal-reflection-fluorescence excitation. We report on total-internal-reflection-fluorescence visualization using rhodamine 6G at 5 μM concentration which results in strongly contrasting pictures. The preferential absorption and the high spatial resolution allow us to detect nanobubbles with diameters of 230 nm and above. We resolve the nucleation dynamics during the water-ethanol-water exchange: within 4 min after exchange the bubbles nucleate and form a stable population. Additionally, we demonstrate that tracer particles near to the nanobubbles are following Brownian motion: the remaining drift flow is weaker than a few micrometers per second at a distance of 400 nm from the nanobubble's center.

摘要

纳米气泡可以使用全内反射荧光激发的光学显微镜观察。我们报告了使用 5 μM 浓度的罗丹明 6G 的全内反射荧光可视化，这导致了强烈对比的图像。优先吸收和高空间分辨率允许我们检测直径为 230nm 及以上的纳米气泡。我们在水-乙醇-水交换过程中解析了成核动力学：在交换后 4 分钟内，气泡成核并形成稳定的群体。此外，我们证明了纳米气泡附近的示踪粒子正在进行布朗运动：在距离纳米气泡中心 400nm 处，剩余的漂移流比每秒几微米还要弱。

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全内反射荧光显微镜用于研究纳米气泡动力学。

Total-internal-reflection-fluorescence microscopy for the study of nanobubble dynamics.

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