用共焦微分动态显微镜对集中、多重散射和主动驱动的荧光系统进行特征描述。

Characterizing concentrated, multiply scattering, and actively driven fluorescent systems with confocal differential dynamic microscopy.

机构信息

Department of Physics and SEAS, Harvard University, Cambridge, Massachusetts 02138, USA.

出版信息

Phys Rev Lett. 2012 May 25;108(21):218103. doi: 10.1103/PhysRevLett.108.218103. Epub 2012 May 22.

DOI:10.1103/PhysRevLett.108.218103

Abstract

We introduce confocal differential dynamic microscopy (ConDDM), a new technique yielding information comparable to that given by light scattering but in dense, opaque, fluorescent samples of micron-sized objects that cannot be probed easily with other existing techniques. We measure the correct wave vector q-dependent structure and hydrodynamic factors of concentrated hard-sphere-like colloids. We characterize concentrated swimming bacteria, observing ballistic motion in the bulk and a new compressed-exponential scaling of dynamics, and determine the velocity distribution; by contrast, near the coverslip, dynamics scale differently, suggesting that bacterial motion near surfaces fundamentally differs from that of freely swimming organisms.

摘要

我们介绍共聚焦微分动态显微镜（ConDDM），这是一种新技术，可提供与光散射相当的信息，但可用于无法用其他现有技术轻松探测的微米级、密集、不透明、荧光样本。我们测量了浓硬球胶体的正确的波矢 q 相关结构和流体力学因素。我们对浓聚游动细菌进行了特征描述，观察到在体相中的弹道运动和动力学的新压缩指数标度，并且确定了速度分布；相比之下，在盖玻片附近，动力学的标度不同，这表明细菌在表面附近的运动与自由游动生物的运动有根本的不同。

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用共焦微分动态显微镜对集中、多重散射和主动驱动的荧光系统进行特征描述。

Characterizing concentrated, multiply scattering, and actively driven fluorescent systems with confocal differential dynamic microscopy.

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用共焦微分动态显微镜对集中、多重散射和主动驱动的荧光系统进行特征描述。

Characterizing concentrated, multiply scattering, and actively driven fluorescent systems with confocal differential dynamic microscopy.

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