Engineering applications development through OHAM in heat and mass transfer during stagnant flow of second-grade nanomaterial

Khursheed Muhammad; Tasawar Hayat; Shaher Momani

doi:10.1142/S0217984924501604

Engineering applications development through OHAM in heat and mass transfer during stagnant flow of second-grade nanomaterial

Khursheed Muhammad
, Tasawar Hayat
, Shaher Momani

Nonlinear Dynamic Research Centre (NDRC)

National University of Sciences and Technology Pakistan
Quaid-I-Azam University

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

This paper investigates the stagnation point flow of a second-grade nanomaterial, considering nanofluid effects via thermophoresis and Brownian motion. The study addresses convective heat and mass transfer conditions within the flow induced by a stretching cylinder. The transformed systems are solved using the optimal homotopy solutions (OHAM) method, revealing the impact of various parameters on the quantities of interest. The results indicate that an increase in curvature, viscoelasticity, velocity ratio and injection parameters leads to an enhancement in velocity, while the opposite trend is observed due to suction. The viscoelasticity and curvature parameters also increase skin friction. Additionally, thermophoresis enhances the temperature and concentration fields, while Brownian motion reduces mass diffusion.

Original language	English
Article number	2450160
Journal	Modern Physics Letters B
Volume	38
Issue number	22
DOIs	https://doi.org/10.1142/S0217984924501604
State	Published - 10 Aug 2024

Keywords

Second grade fluid
convective conditions
nanomaterial
non-linear computations
stagnation point
stretching cylinder

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10.1142/S0217984924501604

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title = "Engineering applications development through OHAM in heat and mass transfer during stagnant flow of second-grade nanomaterial",

abstract = "This paper investigates the stagnation point flow of a second-grade nanomaterial, considering nanofluid effects via thermophoresis and Brownian motion. The study addresses convective heat and mass transfer conditions within the flow induced by a stretching cylinder. The transformed systems are solved using the optimal homotopy solutions (OHAM) method, revealing the impact of various parameters on the quantities of interest. The results indicate that an increase in curvature, viscoelasticity, velocity ratio and injection parameters leads to an enhancement in velocity, while the opposite trend is observed due to suction. The viscoelasticity and curvature parameters also increase skin friction. Additionally, thermophoresis enhances the temperature and concentration fields, while Brownian motion reduces mass diffusion.",

keywords = "Second grade fluid, convective conditions, nanomaterial, non-linear computations, stagnation point, stretching cylinder",

author = "Khursheed Muhammad and Tasawar Hayat and Shaher Momani",

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T1 - Engineering applications development through OHAM in heat and mass transfer during stagnant flow of second-grade nanomaterial

AU - Muhammad, Khursheed

AU - Hayat, Tasawar

AU - Momani, Shaher

PY - 2024/8/10

Y1 - 2024/8/10

N2 - This paper investigates the stagnation point flow of a second-grade nanomaterial, considering nanofluid effects via thermophoresis and Brownian motion. The study addresses convective heat and mass transfer conditions within the flow induced by a stretching cylinder. The transformed systems are solved using the optimal homotopy solutions (OHAM) method, revealing the impact of various parameters on the quantities of interest. The results indicate that an increase in curvature, viscoelasticity, velocity ratio and injection parameters leads to an enhancement in velocity, while the opposite trend is observed due to suction. The viscoelasticity and curvature parameters also increase skin friction. Additionally, thermophoresis enhances the temperature and concentration fields, while Brownian motion reduces mass diffusion.

AB - This paper investigates the stagnation point flow of a second-grade nanomaterial, considering nanofluid effects via thermophoresis and Brownian motion. The study addresses convective heat and mass transfer conditions within the flow induced by a stretching cylinder. The transformed systems are solved using the optimal homotopy solutions (OHAM) method, revealing the impact of various parameters on the quantities of interest. The results indicate that an increase in curvature, viscoelasticity, velocity ratio and injection parameters leads to an enhancement in velocity, while the opposite trend is observed due to suction. The viscoelasticity and curvature parameters also increase skin friction. Additionally, thermophoresis enhances the temperature and concentration fields, while Brownian motion reduces mass diffusion.

KW - Second grade fluid

KW - convective conditions

KW - nanomaterial

KW - non-linear computations

KW - stagnation point

KW - stretching cylinder

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DO - 10.1142/S0217984924501604

M3 - Article

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SN - 0217-9849

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JO - Modern Physics Letters B

JF - Modern Physics Letters B

IS - 22

M1 - 2450160

ER -

Engineering applications development through OHAM in heat and mass transfer during stagnant flow of second-grade nanomaterial

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