Electrokinetic Particle Transport in Micro-/Nanofluidics Direct Numerical Simulation Analysis Surfactant Science Series

Numerous applications of micro-/nanofluidics are related to particle transport in micro-/nanoscale channels, and electrokinetics has proved to be one of the most promising tools to manipulate particles in micro/nanofluidics. Therefore, a comprehensive understanding of electrokinetic particle transport in micro-/nanoscale channels is crucial to the development of micro-/nanofluidic devices.

Electrokinetic Particle Transport in Micro-/Nanofluidics: Direct Numerical Simulation Analysis provides a fundamental understanding of electrokinetic particle transport in micro-/nanofluidics involving electrophoresis, dielectrophoresis, electroosmosis, and induced-charge electroosmosis. The book emphasizes the direct numerical simulation of electrokinetic particle transport phenomena, plus several supportive experimental studies. Using the commercial finite element package COMSOL Multiphysics®, it guides researchers on how to predict the particle transport subjected to electric fields in micro-/nanoscale channels.

Researchers in the micro-/nanofluidics community, who may have limited experience in writing their own codes for numerical simulations, can extend the numerical models and codes presented in this book to their own research and guide the development of real micro-/nanofluidics devices.

Corresponding COMSOL® script files are provided with the book and can be downloaded from the author?s website.

Basics of Electrokinetics in Micro/Nano-fluidics. Numerical Simulations of Electrical Double Layer and Electroosmotic Flow in a Nanopore. Transient Electrokinetic Motion of a Circular Particle in a Microchannel. Electrokinetic Transport of Cylindrical-Shaped Cells in a Straight Microchannel. Shear- and Electrokinetics-Induced Particle Deformation in a Slit Channel. Pair Interaction between Two Colloidal Particles under DC Electric Field. Electrokinetic Translocation of a Cylindrical Particle through a Nanopore: Poisson–Boltzmann Approach. Electrokinetic Translocation of a Cylindrical Particle through a Nanopore: Poisson–Nernst–Planck Multi-ion Model. Field Effect Control of DNA Translocation through a Nanopore. Electrokinetic Particle Translocation through a Nanopore Containing a Floating Electrode.