Dynamics of gyrotactic microorganisms for chemically reactive magnetized 3D Sutterby nanofluid fluid flow comprising non-uniform heat sink-source aspects
暂无分享,去创建一个
[1] W. Khan. Modeling of modified Eyring–Powell nanofluid flow subject to thermal-solutal stratification phenomenon , 2023, Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering.
[2] K. Alharbi,et al. Numerical Solution of Maxwell-Sutterby Nanofluid Flow inside a Stretching Sheet with Thermal Radiation, Exponential Heat Source/Sink, and Bioconvection , 2023, International Journal of Thermofluids.
[3] W. Khan,et al. Thermal radiation and heat sink/source aspects on 3D magnetized Sutterby fluid capturing thermophoresis particle deposition , 2023, International Journal of Modern Physics B.
[4] M. Khan,et al. Effects of activation energy and chemical reaction on unsteady MHD dissipative Darcy–Forchheimer squeezed flow of Casson fluid over horizontal channel , 2023, Scientific Reports.
[5] F. Al-Yarimi,et al. Analysis of the Thomson and Troian velocity slip for the flow of ternary nanofluid past a stretching sheet , 2023, Scientific Reports.
[6] M. Khan,et al. Double diffusion effect on the bio-convective magnetized flow of tangent hyperbolic liquid by a stretched nano-material with Arrhenius Catalysts , 2023, Case Studies in Thermal Engineering.
[7] W. Khan. Dynamics of gyrotactic microorganisms for modified Eyring Powell nanofluid flow with bioconvection and nonlinear radiation aspects , 2023, Waves in Random and Complex Media.
[8] R. Othman,et al. Significance of gyrotactic microorganism and bioconvection analysis for radiative Williamson fluid flow with ferromagnetic nanoparticles , 2023, Thermal Science and Engineering Progress.
[9] F. Alzahrani,et al. Numerical bio-convective assessment for rate type nanofluid influenced by Nield thermal constraints and distinct slip features , 2023, Case Studies in Thermal Engineering.
[10] W. Khan,et al. Significance of bioconvection analysis for thermally stratified 3D Cross nanofluid flow with gyrotactic microorganisms and activation energy aspects , 2023, Thermal Science and Engineering Progress.
[11] W. Khan,et al. Simultaneous features of nonuniform heat sink/source and activation energy in entropy optimized flow of Sutterby fluid subject to thermal radiation , 2023, International Journal of Modern Physics B.
[12] Waqar Azeem Khan,et al. A generalized differential quadrature algorithm for the Sutterby nanofluid flow capturing irreversibility analysis and activation energy aspects , 2023, Waves in Random and Complex Media.
[13] M. ijaz khan,et al. Bioconvection effect in the Carreau nanofluid with Cattaneo–Christov heat flux using stagnation point flow in the entropy generation: Micromachines level study , 2023, Open Physics.
[14] Shuguang Li,et al. Scheduling equal-length jobs with arbitrary sizes on uniform parallel batch machines , 2023, Open Mathematics.
[15] W. Khan,et al. Significance of Chemical Processes and Non-uniform Heat Sink/source Aspects for Time-dependent Polymer Liquid Carrying Nanoparticles , 2022, Journal of Magnetics.
[16] W. Khan,et al. Thermal performance analysis of Sutterby nanoliquid subject to melting heat transportation , 2022, International Journal of Modern Physics B.
[17] W. Khan,et al. Dynamics of stratifications and magnetic dipole for radiative flow of ferromagnetic Sutterby fluid , 2022, ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik.
[18] W. Khan,et al. Impact of magnetized non-linear radiative flow on 3D chemically reactive sutterby nanofluid capturing heat sink/source aspects , 2022, Case Studies in Thermal Engineering.
[19] Waqar Azeem Khan. Impact of time-dependent heat and mass transfer phenomenon for magnetized Sutterby nanofluid flow , 2022, Waves in Random and Complex Media.
[20] Qijia Yao,et al. Unified neural output-constrained control for space manipulator using tan-type barrier Lyapunov function , 2022, Advances in Space Research.
[21] Waqar Azeem Khan,et al. Impact of thermal-solutal stratifications and activation energy aspects on time-dependent polymer nanoliquid , 2022, Waves in Random and Complex Media.
[22] Nehad Ali Shah,et al. Multi-linear regression of triple diffusive convectively heated boundary layer flow with suction and injection: Lie group transformations , 2022, International Journal of Modern Physics B.
[23] Mohammed A. Jameel,et al. A review on electrical and gas-sensing properties of reduced graphene oxide-metal oxide nanocomposites , 2022, Biomass Conversion and Biorefinery.
[24] W. Khan,et al. Numerical analysis for thermal performance of modified Eyring Powell nanofluid flow subject to activation energy and bioconvection dynamic , 2022, Case Studies in Thermal Engineering.
[25] M. Azam. Bioconvection and nonlinear thermal extrusion in development ofchemically reactive Sutterby nano-material due to gyrotactic microorganisms , 2022, International Communications in Heat and Mass Transfer.
[26] M. Irfan,et al. Impact of stratification phenomena on a nonlinear radiative flow of sutterby nanofluid , 2021 .
[27] Kamel Al-khaled,et al. Simultaneous features of Wu's slip, nonlinear thermal radiation and activation energy in unsteady bio-convective flow of Maxwell nanofluid configured by a stretching cylinder , 2021 .
[28] T. Hayat,et al. Entropy minimization for magneto peristaltic transport of Sutterby materials subject to temperature dependent thermal conductivity and non-linear thermal radiation , 2021 .
[29] Sami Ullah Khan,et al. Convective nonlinear thermally developed flow of thixotropic nanoliquid configured by Riga surface with gyrotactic microorganism and activation energy: A bio-technology and thermal extrusion model , 2020 .
[30] M. Irfan,et al. Characteristics of generalized Fourier’s heat flux and homogeneous-heterogeneous reactions in 3D flow of non-Newtonian cross fluid , 2020, International Journal of Numerical Methods for Heat & Fluid Flow.
[31] M. Sheremet,et al. Numerical study of mixed bio-convection associated with a micropolar fluid , 2020 .
[32] W. Khan,et al. Numerical analysis of chemical reaction and non-linear radiation for magneto-cross nanofluid over a stretching cylinder , 2020, Applied Nanoscience.
[33] Muhammad Attique Khan,et al. Physical significance of chemical processes and Lorentz’s forces aspects on Sisko fluid flow in curved configuration , 2020, Soft Computing.
[34] W. Khan,et al. Influence of homogeneous-heterogeneous reaction model for 3D Cross fluid flow: a comparative study , 2020 .
[35] W. Ibrahim,et al. MHD slip flow of upper-convected Maxwell nanofluid over a stretching sheet with chemical reaction , 2020 .
[36] M. Irfan,et al. Importance of heat generation in chemically reactive flow subjected to convectively heated surface , 2020 .
[37] Syed Inayat Ali Shah,et al. Activation energy characteristics of chemically reacting species in multi-route complex reaction mechanism , 2019, Indian Journal of Physics.
[38] W. Khan,et al. Exploring the physical aspects of nanofluid with entropy generation , 2019, Applied Nanoscience.
[39] T Hayat,et al. Nanomaterial based flow of Prandtl-Eyring (non-Newtonian) fluid using Brownian and thermophoretic diffusion with entropy generation , 2019, Comput. Methods Programs Biomed..
[40] M. Irfan,et al. Transport of radiative heat transfer in dissipative Cross nanofluid flow with entropy generation and activation energy , 2019, Physica Scripta.
[41] Tasawar Hayat,et al. Salient aspects of entropy generation optimization in mixed convection nanomaterial flow , 2018, International Journal of Heat and Mass Transfer.
[42] Y. D. Sharma,et al. Analysis of onset of bio-thermal convection in a fluid containing gravitactic microorganisms by the energy method , 2018, Chinese Journal of Physics.
[43] T. Hayat,et al. Entropy generation optimization and activation energy in nonlinear mixed convection flow of a tangent hyperbolic nanofluid , 2018, The European Physical Journal Plus.
[44] Muhammad Imran Khan,et al. Axisymmetric flow of Casson fluid by a swirling cylinder , 2018, Results in Physics.
[45] Muhammad Imran Khan,et al. MHD flow of carbon in micropolar nanofluid with convective heat transfer in the rotating frame , 2017 .
[46] O. Anwar Bég,et al. Numerical solutions for gyrotactic bioconvection in nanofluid-saturated porous media with Stefan blowing and multiple slip effects , 2016, Comput. Math. Appl..
[47] N. Akbar,et al. Nano Sutterby Fluid Model for the Peristaltic Flow in Small Intestines , 2013 .
[48] A. Kuznetsov,et al. Nanofluid bioconvection in water-based suspensions containing nanoparticles and oxytactic microorganisms: oscillatory instability , 2011, Nanoscale research letters.
[49] Andrey V. Kuznetsov,et al. The onset of thermo-bioconvection in a shallow fluid saturated porous layer heated from below in a suspension of oxytactic microorganisms , 2006 .
[50] M. Eissa,et al. Helical Flow of a Sutterby Model Fluid , 1994 .
[51] J. Platt. "Bioconvection Patterns" in Cultures of Free-Swimming Organisms , 1961, Science.
[52] V. S. Pandey,et al. 3D Bioconvective multiple slip flow of chemically reactive Casson nanofluid with gyrotactic micro-organisms , 2019, Heat Transfer-Asian Research.
[53] T. Hayat,et al. Numerical simulation for peristaltic activity of Sutterby fluid with modified Darcy’s law , 2017 .
[54] A. Kuznetsov. Nanofluid bioconvection: interaction of microorganisms oxytactic upswimming, nanoparticle distribution, and heating/cooling from below , 2012 .