Nanoparticle aggregation and electro-osmotic propulsion in peristaltic transport of third-grade nanofluids through porous tube.

Dolui, Soumini; Bhaumik, Bivas; De, Soumen; Changdar, Satyasaran

Dolui, Soumini; Bhaumik, Bivas; De, Soumen; Changdar, Satyasaran.

Afiliación

Dolui S; Department of Applied Mathematics, University of Calcutta, 92, A.P.C. Road, Kolkata 700 009, India. Electronic address: doluisoumini@gmail.com.
Bhaumik B; Department of Mathematics, National Institute of Technology, Rourkela 769008, Odisha, India. Electronic address: bhaumikbivas@gmail.com.
De S; Department of Applied Mathematics, University of Calcutta, 92, A.P.C. Road, Kolkata 700 009, India. Electronic address: soumenisi@gmail.com.
Changdar S; Department of Food Science, University of Copenhagen, Copenhagen, DK-1958, Frederiksberg, Denmark. Electronic address: sach@di.ku.dk.

Comput Biol Med ; 176: 108617, 2024 Jun.

Article en En | MEDLINE | ID: mdl-38772055

ABSTRACT

ABSTRACT

In the modern era, the utilization of electro-kinetic-driven microfluidic pumping procedures spans various biomedical and physiological domains. The present study introduces a mathematical framework for characterizing the hemodynamics of peristaltic blood flow within a porous tube infused with ZrO2 nanoparticles. This model delves into the interactions between buoyancy, electro-osmotic forces, and aggregated nanoparticles to discern their influence on blood flow. We employ a third-grade fluid model to elucidate the rheological behavior of the pseudoplastic fluid which refers to its response to applied shear stress, specifically the relationship between shear rate and viscosity. The collective influence of accommodating heat convection, joule heating and aggregated nanoparticles contributes to the thermal behavior of fluids. The distribution of electric potential within the electric double layer (EDL) is predicted by solving the Poisson-Boltzmann equation. The rescaled equations are simplified using the lubrication and Debye-Hückel models as the underlying frameworks. The novel homotopy perturbation method is employed to obtain solutions for the finalized non-linear partial differential equation. Theoretical assessment of hemodynamic impacts involves plotting graphical configurations for various emerging parameters. As electro-osmotic parameter increase, the bloodstream encounters greater impedance, thereby enhancing the effectiveness of electro-osmotic assistance. Concurrently, elevated convective heat markedly reduces the rate of heat transfer, potentially resulting in a drop in blood temperature. It is important to note that maximum shear stress occurs when the artery is positioned horizontally, underscoring the significant impact of arterial alignment on wall shear stress. Skin friction intensifies with the increasing wall permeability as aggregated nanofluids pass through the arterial conduit. Therefore, aggregation of nanoparticles into the bloodstream yields a broader spectrum of distinctive physiological features. In summary, these findings enable more effective tool and device designs for addressing medication administration challenges and electro-therapies.

Asunto(s)

Nanopartículas; Nanopartículas/química; Humanos; Porosidad; Electroósmosis; Peristaltismo/fisiología; Ósmosis; Circonio/química

Palabras clave

Aggregation of nanoparticles; Electro-hydrodynamics flow; Thermal convection; Third-grade nanofluid; Wall permeability

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Texto completo: 1 Colección: 01-internacional Base de datos: MEDLINE Asunto principal: Nanopartículas Límite: Humans Idioma: En Revista: Comput Biol Med Año: 2024 Tipo del documento: Article Pais de publicación: Estados Unidos

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