• DocumentCode
    1391504
  • Title

    Fourier-Bessel Series Modeling of Dielectrophoretic Bionanoparticle Transport: Principles and Applications

  • Author

    Bakewell, David J. ; Chichenkov, Aleksandr

  • Author_Institution
    Dept. of Electr. Eng. & Electron., Univ. of Liverpool, Liverpool, UK
  • Volume
    11
  • Issue
    1
  • fYear
    2012
  • fDate
    3/1/2012 12:00:00 AM
  • Firstpage
    79
  • Lastpage
    86
  • Abstract
    Principles and applications are described for a Fourier-Bessel series model that predicts the transport of bionanoparticles driven by a dielectrophoretic (DEP) force and randomized by Brownian motion. The model is applicable for a dielectrophoretic force that spatially decays from the electrode array according to a reciprocal-law; that is, in the near field of a planar interdigitated array or in the far field where other long range forces assist DEP transport, e.g., ac electro-osmosis. Capabilities of the model are demonstrated for estimating and decomposing data typical of dielectrophoretic bionanoparticle collection experiments. An important approximation, for moderately strong DEP forces, is that a collection can largely be described by a single exponential profile with a square-law dependence on microdevice chamber height. Applications of the model demonstrate transformation and representation of time-dependent bionanoparticle transport in the frequency domain and prediction of a modulation bandwidth that concurs with experimental observations.
  • Keywords
    Brownian motion; Fourier series; RNA; biochemistry; biological techniques; electrophoresis; molecular biophysics; nanobiotechnology; nanoparticles; physiological models; Brownian motion; Fourier-Bessel series model; Fourier-bessel series modeling; dielectrophoretic bionanoparticle collection experiments; dielectrophoretic bionanoparticle transport; dielectrophoretic force; electrode array; electroosmosis; microdevice chamber height; reciprocal-law; single exponential profile; square-law dependence; time-dependent bionanoparticle transport; Arrays; Data models; Electrodes; Force; Mathematical model; Nanoparticles; Switches; Bionanoparticles; Fokker Planck equation; Fourier-Bessel series; dielectrophoresis; microdevices; modified diffusion equation; modulation bandwidth; Diffusion; Electrophoresis; Fourier Analysis; Models, Chemical; Nanoparticles;
  • fLanguage
    English
  • Journal_Title
    NanoBioscience, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1536-1241
  • Type

    jour

  • DOI
    10.1109/TNB.2011.2178430
  • Filename
    6096420