Applications of variable thermal features for the bioconvective flow of Jeffrey nanofluids due to stretching surface with masssuction effects: Cattaneo-Christov model

S. U. KHAN, M. GARAYEV, ADNAN, K. RAMESH, M. EL MELIGY, D. ABDUVALIEVA, M. I. KHAN

doi:10.1007/s10483-025-3213-8

2025 , Vol. 46 >Issue 2: 391 - 402

DOI: https://doi.org/10.1007/s10483-025-3213-8

Applications of variable thermal features for the bioconvective flow of Jeffrey nanofluids due to stretching surface with masssuction effects: Cattaneo-Christov model

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^1.Department of Mathematics, Namal University, Mianwali 42250, Pakistan
^2.Department of Mathematics, College of Science, King Saud University, Riyadh 11421, Saudi Arabia
^3.Department of Mathematics, Mohi-ud-Din Islamic University, Nerian Sharif 12080, Pakistan
^4.Department of Pure and Applied Mathematics, School of Mathematical Sciences, Sunway University, Petaling Jaya 47500, Malaysia
^5.Department of Mathematics, Graphic Era (Deemed to be University), Dehradun, Uttarakhand 248002, India
^6.Department of Mathematics, School of Chemical Engineering and Physical Sciences, Lovely Professional University, Punjab 144411, India
^7.Jadara University Research Center, Jadara University, Irbid 21110, Jordan
^8.Applied Science Research Center, Applied Science Private University, Amman 11937, Jordan
^9.Department of Mathematics and Information Technologies, Tashkent State Pedagogical University, Tashkent 100070, Uzbekistan
^10.Department of Mechanics and Engineering Science, Peking University, Beijing 100871, China

M. I. KHAN, E-mail: 2106391391@pku.edu.cn

Received date: 2024-08-25

Revised date: 2024-12-06

Online published: 2025-02-02

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Abstract

The thermal nanofluids have garnered widespread attention for their use in multiple thermal systems, including heating processes, sustainable energy, and nuclear reactions. Research on nanofluids has revealed that the thermal efficiencies of such materials are adversely affected by various thermal features. The purpose of the current work is to demonstrate the thermal analysis of Jeffrey nanofluids with the suspension of microorganisms in the presence of variable thermal sources. The variable effects of thermal conductivity, Brownian diffusivity, and motile density are utilized. The investigated model also reveals the contributions of radiation phenomena and chemical reactions. A porous, saturated, moving surface with a suction phenomenon promotes flow. The modeling of the problem is based on the implementation of the Cattaneo-Christov approach. The convective thermal constraints are used to promote the heat transfer features. A simplified form of the governing model is treated with the assistance of a shooting technique. The physical effects of different parameters for the problem are presented. The current problem justifies its applications in heat transfer, coating processes, heat exchangers, cooling systems in microelectronics, solar systems, chemical processes, etc.

Key words： Jeffrey nanofluid; bioconvection effect; variable thermal consequence; chemical reaction; numerical simulation

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S. U. KHAN, M. GARAYEV, ADNAN, K. RAMESH, M. EL MELIGY, D. ABDUVALIEVA, M. I. KHAN . Applications of variable thermal features for the bioconvective flow of Jeffrey nanofluids due to stretching surface with masssuction effects: Cattaneo-Christov model[J]. Applied Mathematics and Mechanics, 2025 , 46(2) : 391 -402 . DOI: 10.1007/s10483-025-3213-8

References

[1]	WANG, B. F., ZHOU, Q., and SUN, C., Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement. Science Advances, 6(21), eaaz8239 (2020)
[2]	WU, J. Z., WANG, B. F., and ZHOU, Q. Massive heat transfer enhancement of Rayleigh-Bénard turbulence over rough surfaces and under horizontal vibration. Acta Mechanica Sinica, 38(2), 321319 (2022)
[3]	HUANG, Z. L., WU, J. Z., GUO, X. L., ZHAO, C. B., WANG, B. F., CHONG, K. L., and ZHOU, Q. Unifying constitutive law of vibroconvective turbulence in microgravity. Journal of Fluid Mechanics, 987, A14 (2024)
[4]	WU, J. Z., WANG, B. F., CHONG, K. L., DONG, Y. H., SUN, C., and ZHOU, Q. Vibration-induced ‘anti-gravity’ tames thermal turbulence at high Rayleigh numbers. Journal of Fluid Mechanics, 951, A13 (2022)
[5]	HSIAO, K. L. Combined electrical MHD heat transfer thermal extrusion system using Maxwell fluid with radiative and viscous dissipation effects. Applied Thermal Engineering, 112, 1281–1288 (2017)
[6]	HSIAO, K. L. To promote radiation electrical MHD activation energy thermal extrusion manufacturing system efficiency by using Carreau-nanofluid with parameters control method. Energy, 130, 486–499 (2017)
[7]	HSIAO, K. L. Stagnation electrical MHD nanofluid mixed convection with slip boundary on a stretching sheet. Applied Thermal Engineering, 98, 850–861 (2016)
[8]	HSIAO, K. L. Micropolar nanofluid flow with MHD and viscous dissipation effects towards a stretching sheet with multimedia feature. International Journal of Heat and Mass Transfer, 112, 983–990 (2017)
[9]	NAZIR, W., JAVED, T., ALI, N., and MUBBASHAR, N. Effects of radiative heat flux and heat generation on magnetohydodynamics natural convection flow of nanofluid inside a porous triangular cavity with thermal boundary conditions. Numerical Methods for Partial Differential Equations, 40(2), e22768 (2024)
[10]	BILAL, S., PAN, K., HUSSAIN, Z., KADA, B., PASHA, A. A., and KHAN, W. A. Darcy-Forchheimer chemically reactive bidirectional flow of nanofluid with magneto-bioconvection and Cattaneo-Christov properties. Tribology International, 193, 109313 (2024)
[11]	RAHMAN, M., TURKYILMAZOGLU, M., and MUSHTAQ, Z. Effects of multiple shapes for steady flow with transformer oil+Fe₃O₄+TiO₂ between two stretchable rotating disks. Applied Mathematics and Mechanics (English Edition), 45(2), 373–388 (2024) https://doi.org/10.1007/s10483-024-3088-7
[12]	ZAHEER, M., ABBAS, S. Z., HUANG, N., and ELMASRY, Y. Analysis of buoyancy features on magneto hydrodynamic stagnation point flow of nanofluid using homotopy analysis method. International Journal of Heat and Mass Transfer, 221, 125045 (2024)
[13]	ISLAM, A., MAHMOOD, Z., and KHAN, U. Significance of mixed convective double diffusive MHD stagnation point flow of nanofluid over a vertical surface with heat generation. Proceedings of the Institution of Mechanical Engineers, Part N: Journal of Nanomaterials, Nanoengineering and Nanosystems (2024) https://doi.org/10.1177/23977914231210798
[14]	HAIDER, J. A., GUL, S., GEPREEL, K. A., KHAN, M. N., and LONE, S. A., Impact of heat transfer on peristaltic flow of nanofluid and its applications in real world problems. Modern Physics Letters B, 38(6), 2350244 (2024)
[15]	RAMASEKHAR, G. and JAWAD, M. Characteristics of MWCNT, SWCNT, Cu and water based on magnetized flow of nanofluid with Soret and Dufour effects induced by moving wedge: consequence of Falkner-Skan power law. Numerical Heat Transfer, Part A: Applications (2024) https://doi.org/10.1080/10407782.2024.2341270
[16]	AL ARNI, S., EL JERY, A., ULLAH, Z., ALSULAMI, M. D., EL ZAHAR, E. R., SEDDEK, L. F., and BEN KHEDHER, N. Oscillatory and non-oscillatory analysis of heat and mass transfer of Darcian MHD flow of nanofluid along inclined radiating plate with Joule heating and multiple slip effects: microgravity analysis. Case Studies in Thermal Engineering, 60, 104681 (2024)
[17]	ELBOUGHDIRI, N., JAVID, K., SHEHZAD, M. Q., and BENGUERBA, Y. Influence of chemical reaction on electro-osmotic flow of nanofluid through convergent multi-sinusoidal passages. Case Studies in Thermal Engineering, 54, 103955 (2024)
[18]	LI, S., FAIZAN, M., ALI, F., RAMASEKHAR, G., MUHAMMAD, T., KHALIFA, H. A. E., and AHMAD, Z. Modelling and analysis of heat transfer in MHD stagnation point flow of Maxwell nanofluid over a porous rotating disk. Alexandria Engineering Journal, 91, 237–248 (2024)
[19]	SAHOO, R. K., MISHRA, S. R., and PANDA, S. Effective properties of binary chemical reaction with Brownian and thermophoresis on the radiative flow of nanofluid within an inclined heated channel. Colloid and Polymer Science, 302, 1337–1352 (2024)
[20]	MISHRA, S. K., TRIPURE, A., MISHRA, A., and SINGH, P. Effects of vibrational flow on nanofluid flow behavior under different temperature boundary conditions. Numerical Heat Transfer, Part A: Applications (2024) https://doi.org/10.1080/10407782.2024.2340071
[21]	REZAEE, D. Linear temporal stability of Jeffery-Hamel flow of nanofluids. European Journal of Mechanics-B/Fluids, 107, 1–16 (2024)
[22]	MAHITHA, O., GOLLA, V. K. A., AKGüL, A., and BANGALORE, R. K. New YAC time-fractional derivative approach for water-based hydromagnetic chemically reacting radiative flow of nanofluid with copper nanoparticles past an upright plate. Numerical Heat Transfer, Part B: Fundamentals (2024) https://doi.org/10.1080/10407790.2024.2345703
[23]	WAQAS, H., HUSSAIN, M., ALQARNI, M. S., EID, M. R., and MUHAMMAD, T. Numerical simulation for magnetic dipole in bioconvection flow of Jeffrey nanofluid with swimming motile microorganisms. Waves in Random and Complex Media, 34(3), 1958–1975 (2024)
[24]	PUNEETH, V., ALI, F., KHAN, M. R., ANWAR, M. S., and AHAMMAD, N. A. Theoretical analysis of the thermal characteristics of Ree-Eyring nanofluid flowing past a stretching sheet due to bioconvection. Biomass Conversion and Biorefinery, 14(7), 8649–8660 (2024)
[25]	IQBAL, M., KHAN, N. S., KHAN, W., HASSINE, S. H., ALHABEEB, S. A., and KHALIFA, H. A. E. Partially ionized bioconvection Eyring-Powell nanofluid flow with gyrotactic microorganisms in thermal system. Thermal Science and Engineering Progress, 47, 102283 (2024)
[26]	SHAMSHUDDIN, M. D., SAEED, A., MISHRA, S. R., KATTA, R., and EID, M. R. Homotopic simulation of MHD bioconvective flow of water-based hybrid nanofluid over a thermal convective exponential stretching surface. International Journal of Numerical Methods for Heat & Fluid Flow, 34(1), 31–53 (2024)
[27]	YU, L. P., LI, Y. J., PUNEETH, V., SINGH, C., SINGHAL, A., and ANWAR, M. S. Thermal optimisation through the stratified bioconvective jetflow of nanofluid. Numerical Heat Transfer, Part B: Fundamentals, 85(6), 791–804 (2024)
[28]	ABBAS, M., KHAN, N., and SHEHZAD, S. A. Numerical analysis of Marangoni convected dusty second-grade nanofluid flow in a suspension of chemically reactive microorganisms. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 238(10), 4400–4417 (2024)
[29]	GASMI, H., OBALALU, A. M., AKINDELE, A. O., SALAUDEEN, S. A., KHAN, U., ISHAK, A., ABBAS, A., MUHAMMAD, T., HUSSAIN, S. M., and ABED, A. M. Thermal performance of a motile-microorganism within the two-phase nanofluid flow for the distinct non-Newtonian models on static and moving surfaces. Case Studies in Thermal Engineering, 58, 104392 (2024)
[30]	JAWAD, M., HUSSAIN, S., OUDINA, F. M., and SHEHZAD, K. Insinuation of radiative bio-convective MHD flow of Casson nanofluid with activation energy and swimming microorganisms. Mathematical Modelling of Fluid Dynamics and Nanofluids, 343-362 (2024)
[31]	HUSSAIN, S. M., MAJEED, A., IJAZ, N., OMER, A. S. A., KHAN, I., MEDANI, M., and KHEDHER, N. B. Heat transfer in three dimensional micropolar based nanofluid with electromagnetic waves in the presence of eukaryotic microbes. Alexandria Engineering Journal, 94, 339–353 (2024)
[32]	RASHED, A. S., EHSAN, H. N., and MABROUK, S. M. Influence of gyrotactic microorganisms on bioconvection in electromagnetohydrodynamic hybrid nanofluid through a permeable sheet. Computation, 12(1), 17 (2024)
[33]	KHAN, M. I., AL KHALED, K., KHAN, S. U., IMTIAZ, M., and NORBERDIYEVA, M. Combined effects of nonlinear thermal radiation and suction/injection on bioconvective boundary layer of Maxwell nanofluid over a porous movable surface. Numerical Heat Transfer, Part A: Applications (2024) https://doi.org/10.1080/10407782.2024.2372039
[34]	TURKYILMAZOGLU, M. The analytical solution of mixed convection heat transfer and fluid flow of a MHD viscoelastic fluid over a permeable stretching surface. International Journal of Mechanical Sciences, 77, 263–268 (2013)

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