Modeling bioconvective mixed convection of non-newtonian nanofluids using finite difference approach: A Jeffrey fluid model

The bioconvective mixed convection flow has engineered significant applications in various industrial processes, biotechnology systems and biomedical engineering. The objective of current analysis is to analyze a two-dimensional bioconvective flow of non-Newtonian nanofluid in presence of mixed conv...

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Published inTribology international Vol. 212; p. 110979
Main Author Khan, M. Ijaz
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.12.2025
Subjects
Bioconvection
Brownian motion and thermophoresis
Finite difference Scheme
Non-Newtonian material
Non-Newtonian material
Bioconvection
Finite difference Scheme
Brownian motion and thermophoresis
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ISSN0301-679X
DOI10.1016/j.triboint.2025.110979

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Abstract The bioconvective mixed convection flow has engineered significant applications in various industrial processes, biotechnology systems and biomedical engineering. The objective of current analysis is to analyze a two-dimensional bioconvective flow of non-Newtonian nanofluid in presence of mixed convection effects. The flow is subject to stretched cylinder. The Jeffrey fluid model is retained in order to evaluate the rheological aspects of non-Newtonian material. The motivated bioconvective problem addresses the heat and mass transfer impact in complex systems. The numerical simulations are performed with implementation of finite difference method (FDM). Physical aspects behind variation of parameters are graphically intended. It has been predicted that fluid velocity enhances due to Grashof number and buoyancy ratio parameter. The microorganisms profile declined due to higher Peclet number. The findings are particularly relevant to the design of nanofluidic heat exchangers, bio-convective cooling technologies, microbial fuel systems, and MHD-based polymer processing devices.
AbstractList The bioconvective mixed convection flow has engineered significant applications in various industrial processes, biotechnology systems and biomedical engineering. The objective of current analysis is to analyze a two-dimensional bioconvective flow of non-Newtonian nanofluid in presence of mixed convection effects. The flow is subject to stretched cylinder. The Jeffrey fluid model is retained in order to evaluate the rheological aspects of non-Newtonian material. The motivated bioconvective problem addresses the heat and mass transfer impact in complex systems. The numerical simulations are performed with implementation of finite difference method (FDM). Physical aspects behind variation of parameters are graphically intended. It has been predicted that fluid velocity enhances due to Grashof number and buoyancy ratio parameter. The microorganisms profile declined due to higher Peclet number. The findings are particularly relevant to the design of nanofluidic heat exchangers, bio-convective cooling technologies, microbial fuel systems, and MHD-based polymer processing devices.
ArticleNumber 110979
Author Khan, M. Ijaz
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  givenname: M. Ijaz
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  organization: Department of Mechanical Engineering, College of Engineering, Prince Mohammad Bin Fahd University, Al-Khobar, Saudi Arabia
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Bioconvection
Finite difference Scheme
Brownian motion and thermophoresis
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  doi: 10.1007/s40430-019-1942-1
– volume: 7
  start-page: 755
  issue: 4
  year: 2018
  ident: 10.1016/j.triboint.2025.110979_bib49
  article-title: Analytical and numerical treatment of a nano-bioconvection flow model in the presence of nanoparticles and gyrotactic microorganisms
  publication-title: J Nanofluids
  doi: 10.1166/jon.2018.1489
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Snippet The bioconvective mixed convection flow has engineered significant applications in various industrial processes, biotechnology systems and biomedical...
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StartPage 110979
SubjectTerms Bioconvection
Brownian motion and thermophoresis
Finite difference Scheme
Non-Newtonian material
Title Modeling bioconvective mixed convection of non-newtonian nanofluids using finite difference approach: A Jeffrey fluid model
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