Tracking Brownian motion in three dimensions and characterization of individual nanoparticles using a fiber-based high-finesse microcavity

The dynamics of nanosystems in solution contain a wealth of information with relevance for diverse fields ranging from materials science to biology and biomedical applications. When nanosystems are marked with fluorophores or strong scatterers, it is possible to track their position and reveal inter...

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Bibliographic Details
Published in:Nature communications 2021-11, Vol.12 (1), p.6385-6385, Article 6385
Main Authors: Kohler, Larissa, Mader, Matthias, Kern, Christian, Wegener, Martin, Hunger, David
Format: Article
Language:English
Subjects:
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9/10
Biocompatibility
Biomedical materials
Brownian motion
Chemical compounds
Direct laser writing
Dispersion
Experiments
Fluorescence
Fluorophores
Humanities and Social Sciences
Labeling
Lasers
Materials science
Microfluidic devices
Microfluidics
multidisciplinary
Nanomaterials
Nanoparticles
Nanospheres
Physical properties
Polarizability
Refractivity
Science
Science (multidisciplinary)
Sensors
Silicon dioxide
Spatial discrimination
Spatial resolution
Temporal resolution
Three dimensional motion
Tracking
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Summary:The dynamics of nanosystems in solution contain a wealth of information with relevance for diverse fields ranging from materials science to biology and biomedical applications. When nanosystems are marked with fluorophores or strong scatterers, it is possible to track their position and reveal internal motion with high spatial and temporal resolution. However, markers can be toxic, expensive, or change the object’s intrinsic properties. Here, we simultaneously measure dispersive frequency shifts of three transverse modes of a high-finesse microcavity to obtain the three-dimensional path of unlabeled SiO 2 nanospheres with 300  μ s temporal and down to 8 nm spatial resolution. This allows us to quantitatively determine properties such as the polarizability, hydrodynamic radius, and effective refractive index. The fiber-based cavity is integrated in a direct-laser-written microfluidic device that enables the precise control of the fluid with ultra-small sample volumes. Our approach enables quantitative nanomaterial characterization and the analysis of biomolecular motion at high bandwidth. Tracking of nanoparticle dynamics in solution often require labelling. Here, the authors use a high-finesse microcavity and simultaneously measure dispersive frequency shifts of three transverse modes, demonstrating 3D tracking of unlabelled single nanospheres, and quantitatively determine their physical properties.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-021-26719-5