Title: Micro and NanosystemsImported from Authenticus Search for Journal Publications

Vol. 7 No. 3

Pages: 142-147

ISSN: 1876-4029

Publisher: Bentham Science

Scopus - 2 Citations

Authenticus ID: P-00K-7GP

DOI: 10.2174/1876402908666160106000131

Abstract (EN): Traditional grid-based numerical methods, such as finite volume method (FVM), are not suitable to simulate multiphase biofluids (such as blood) at the microscale level. Alternatively, meshfree Lagrangian methods can deal with two or more finely dispersed phases moving relatively to each other. The Moving Particle Semi-Implicit Method (MPS), used in this study, is a deterministic particle method based on a Lagrangian technique to simulate incompressible flows. The advantages of particle methods over traditional grid-based numerical methods have motivated several researchers to implement them into a wide range of studies in computational biomicrofluidics. The main aim of this paper is to evaluate the accuracy of the MPS method by comparing it with numerical simulations performed by an FVM. Hence, simulations of a Newtonian fluid flowing through a constriction were performed for both methods. For the MPS, a section of the channel of 30*11.5*11.5 ¿m was simulated using periodic boundary conditions. The obtained results have provided indications that, if the initial particle distance is sufficiently small, the MPS method can calculate accurately velocity profiles in the proposed channel. © 2015 Bentham Science Publishers.

Language: English

Type (Professor's evaluation): Scientific