Fluid flow and heat transfer investigation of blood with nanoparticles through porous vessels in the presence of magnetic field

Usman, Muhammad; Din, Syed Tauseef Mohyud; Zubair, Tamour; Hamid, Muhammad; Wang, Wei

doi:10.1177/1748301818788661

Cited by 8 publications

(4 citation statements)

References 34 publications

(80 reference statements)

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“…It can be seen from this figure that the temperature, nanoparticle volume fraction, and microorganisms are decreased with the increase of Nt , whereas the velocity is increased. The reason for the decreasing density of the motile microorganisms profile is the increasing temperature difference between the ambient fluid and wall, which has a result on the distribution of microorganisms . A similar pattern was also noticed by many researchers.…”

Section: Resultssupporting

confidence: 78%

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MHD boundary layer bionanoconvective non‐Newtonian flow past a needle with Stefan blowing

Amirsom

Uddin

Ismail

2018

Heat Trans. Asian Res.

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The purpose of the article is to present a transport model for magnetohydrodynamics‐forced convective non‐Newtonian boundary flow from a thin needle in a nanofluid in the presence of microorganisms and Stefan blowing. The governing equations are reduced to ordinary differential equations with the help of similarity transformations and then numerically solved by using the Matlab bvp4c function. The effect of various emerging parameters on the flow field, heat, mass, and density of motile microorganisms transfer was computed and studied. It was found that some of the parameters have an important effect on the boundary layer thickness. Justification with earlier simpler model in the absence of magnetic field is included. The model finds applications in various transdermal delivery system, biomedical electromagnetic treatments and to design new medical devices for cell delivery to the central nervous system.

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Section: Resultssupporting

confidence: 78%

“…The increase in Nb leads to an increase in the density of motile microorganism profile. The reason for this phenomenon is the increment in the difference of the nanoparticle volume fraction among the ambient fluid and wall …”

Section: Resultsmentioning

confidence: 99%

MHD boundary layer bionanoconvective non‐Newtonian flow past a needle with Stefan blowing

Amirsom

Uddin

Ismail

2018

Heat Trans. Asian Res.

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“…A model on pulsatile blood flow in a bed that is homogenous and porous in the presence of an inclined magnetic field with time suction was carried out by Ogulu and Amos [3]. Muhammed Usman and Syed Tauseef Mohyud Din [4] did a study investigating fluid flow and heat transfer of blood that has Nanoparticles through a vessel that is porous with the presence of a magnetic field while Asma Khalid [5] did a study on MHD blood flow whose medium is porous and has carbon Nano-tubes and thermal analysis. His research showed that when the carbon-nanotubes volume is increased, there is an increase in the velocity and the temperature.…”

Section: Introductionmentioning

confidence: 99%

Impact of Thermal Radiation and Heat Source on MHD Blood Flow with an Inclined Magnetic Field in Treating Tumor and Low Blood

Omamoke

Amos

Jatari

2020

ARJOM

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In this paper, we will be analyzing the impact of thermal radiation and heat source on blood flow past a horizontal channel that is permeable with an applied magnetic field that is inclined at variable angles. The non-linear higher partial differential equation which is the governing equation is transformed to ordinary differential equations using non-dimensional variable to non-dimensional equations that is then solved analytically with the application of required boundary conditions for the blood flow and temperature equations which is a function of y and t. Parameters that are varied shows an effect on the blood flow and temperature profile with the presentation of results shown graphically and results clearly discussed. Observations from the research shows that when the thermal radiation increases, there will be a mixed effect in the flow of blood, increase in the magnetic field on the artery shows an increase in flow of blood while the blood flow reduces and the temperature of the blood increases when the heat source is increased. Other parameters also shows an effect on the flow of the blood.

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“…Blood, which is composed of plasma, white and red cells, may be considered one of nature's most essential multi-segment mixes. It can be considered as the third-grade non-Newtonian fluid 19 . In the latter work and with the use of the least squares approach, the authors studied the blood flow including nanoparticles via porous blood arteries in the presence of a magnetic field and heat transfer.…”

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confidence: 99%

Unraveling the nature of nano-diamonds and silica in a catheterized tapered artery: highlights into hydrophilic traits

Abdelsalam

Bhatti

2023

Sci Rep

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In this work, we observe the behavior of a hybrid nanofluidic model containing nanodiamonds and silica nanoparticles. The nanofluid propagates through a catheterized tapered artery with three distinct configurations: converging tapered, non-tapered and diverging tapered arteries. In order to assess the rheological properties of the blood, the third-grade non-Newtonian fluid is employed in the flow model such that the Newtonian versus non-Newtonian effects are revealed. The system of equations governing the flow is modeled under magnetic field and with heat transfer, then solved in a closed form using the perturbation approach for the pertinent parameters. The interpretations of the physical variables of interest, such as the velocity, temperature and wall shear stress, are explained. The integration of diamonds and silica nanoparticles give rise to diverse of biological applications since they are used in the drug delivery and biological imaging in genetic materials due to their hydrophilic surfaces. The present mathematical analysis lays a solid foundation on possible therapeutic applications in biomedicine.

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Fluid flow and heat transfer investigation of blood with nanoparticles through porous vessels in the presence of magnetic field

Cited by 8 publications

References 34 publications

MHD boundary layer bionanoconvective non‐Newtonian flow past a needle with Stefan blowing

MHD boundary layer bionanoconvective non‐Newtonian flow past a needle with Stefan blowing

Impact of Thermal Radiation and Heat Source on MHD Blood Flow with an Inclined Magnetic Field in Treating Tumor and Low Blood

Unraveling the nature of nano-diamonds and silica in a catheterized tapered artery: highlights into hydrophilic traits

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