Open AccessSimulation of single particle flowing in a microfluidic device using molecular dynamics method
Author(s) -
Sparısoma Viridi,
Freddy Haryanto,
Isa Anshori,
Mohammad Haekal
Publication year - 2020
Publication title -
journal of physics. conference series
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.21
H-Index - 85
eISSN - 1742-6596
pISSN - 1742-6588
DOI - 10.1088/1742-6596/1505/1/012062
Subject(s) - mechanics , hagen–poiseuille equation , particle (ecology) , microfluidics , fluid dynamics , channel (broadcasting) , separator (oil production) , inlet , molecular dynamics , computational fluid dynamics , microchannel , position (finance) , trajectory , work (physics) , volumetric flow rate , flow (mathematics) , materials science , physics , nanotechnology , computer science , mechanical engineering , engineering , computer network , oceanography , finance , quantum mechanics , astronomy , economics , geology , thermodynamics
Blood cells are modeled as spherical particles that flow through a microfluidic device with one inlet and two outlet channels, which is designed as a separator of blood particles. Molecular dynamics (MD) method was used intuitively in the simulation with the help of Semi-Circle Segmented Path Generator (SCSPG) as an approximation in creating fluid profile along the device channel. The trajectories generated from SCSPG was advanced using a fully developed Poiseuille flow with maximum fluid speed on the trajectories and the tails of speed distribution which was extended to the size of the channel with speed of zero at the channel walls. It has been observed that for a single particle trajectory the outlet channel was chosen by the particle depends on the axial position of the particles. Mass of particle determines how hard the particle deflects due to fluid profile. A better design is proposed in this work for separating two groups of particles with different size.