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Bibliographic Details
Main Authors: de Jong, Flip, Diez-Silva, Pablo, Chen, Jui-Kai, Pérez-Peláez, Raúl, Seth, Sudipta, Balakrishnan, Harishankar, Shih, Bing-Yang, Fransen, Senne, Van Roy, Wim, Rosmeulen, Maarten, Nonell, Santi, Rocha, Susana, Klymchenko, Andrey, Liz-Marzán, Luis, Bresolí-Obach, Roger, Marqués, Manuel I., Hofkens, Johan, Buscalioni, Rafael Delgado, Louis, Boris
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.23839
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Table of Contents:
  • Sorting, filtering, moving and controlling colloidal particles is crucial in many fields, ranging from chemistry to biology and physics. Dielectrophoresis is an outstanding tool for the manipulation of small particles by AC electric fields, due to its high selectivity and the absence of the need for labels. We use a new theoretical-experimental approach to study the dynamics of fluorescently labeled polystyrene nanoparticles of 200 nm under positive and negative dielectrophoresis conditions. Our multiplane widefield microscopy technique combined with single particle tracking offers real-time ($>$ 100 fps) superresolved visualization of colloidal dynamics in three spatial dimensions. This real-time 3D imaging technique allows the reconstruction of superresolved trajectories, enabling the visualisation of local forces with unprecedented detail. To interpret this data, a dedicated multiscale modeling approach was developed, targeting a direct comparison between theory and experiment. In the current model DEP and electro-osmotic forces were considered. Under positive DEP conditions, this resulted in a very good agreement with experiment. Under negative DEP conditions, the agreement is less clear, indicating the importance of other effects. This illustrates the potential of this combined 3D imaging and modeling approach to validate and refine our theoretical understanding of AC field induced colloidal dynamics. This framework is broadly applicable to other complex fluid or microfluidic motion.