Nanofluid plays a crucial role in addressing the heat transmission challenges facing industries including chemical processing systems, automobile radiators, spacecraft design, concrete heating, solar thermal conversion etc. Consequently, this research is devoted to analyzing radiation mechanism, thermophoresis and Brownian motion under unique conditions, specifically, temperature gradient within liquids with limiting viscosities or plastic dynamic viscosity at zero infinite shear rate. To...

This study examines the potential of using nanofluids in solar thermal energy systems. Nanofluids are known to exhibit high convection heat transfer coefficients, low specific heat, and density, making them ideal for improving performance However, this computational investigates application Cattaneo-Christov flux on cylindrical surfaces carbon nanotube (CNT) hybrid nanofluids, use a solar-powered ship. The work utilizes numerical simulations analyze fluid flow characteristics nanofluids....

The demand for efficient applications of solar energy and nanomaterials has grown significantly in recent years due to industrial needs the desire minimize consumption costs. However, efficiency photovoltaic cells solar-powered ships is highly dependent on radiation. In this study, a model installation parabolic trough surface collector (PTSC) was developed achieve high temperatures ships. current study analyzed thermal characterization function under effect heat radiation, magnetic field,...

This study explores thermal criticality and dissipation involving a two-step reaction in hyperbolic tangential fluid flow quadratic Boussinesq approximation to model the complex internal heat transfer mechanisms during combustion. Subject suitable convective boundary conditions, transformed energy momentum equations are numerically solved using Galerkin integration coupled with weighted residual scheme. The outcomes disseminated variety of graphs illustrate for parametric sensitivities...

Simulation of non-Darcian Casson flow subject to a second-order velocity slip and heat transfer due nanofluid over permeable stretching surface is exemplified numerically. The interaction quite different from the first-order as it results in two parameters that can effectively regulate boundary layer development. To best authors' knowledge, this parameter was here incorporated for first time such field radiative flow. model, which governed by system PDEs, accomplishes Chebyshev collocation...

Solar energy is the most important heat source from sun, with photovoltaic cells, solar power plates, lights, and pumping water being widely used. This study looks at analysis a method for increasing efficacy of aircraft by combining nano-technological energy. To enrich research on wings, built investigation transfer employing hybrid nano-fluid past inside parabolic trough collector (PTSC). The thermal referred to as radiative flow. efficiency wings was validated different qualities such...

The recent advancements in using micro-organisms effectively for biofuels are the key reason conducting this study. Therefore, current theoretical work addresses Oswald – DeWaele power-law models of bioconvection nanofluid flow containing both nanoparticles and gyrotactic microorganisms. This study has examined two major elements microorganisms: swimming behavior development structures. In addition, Lie-group approach transformations is used to establish similarity representations governing...

The unsteady squeezed flow of two-dimensional MHD conducting non-Newtonian fluid in the presence solar radiation is exemplified theoretically and numerically. Physically, to minimize energy used system, we need monitor processes heat mass transfer process. In this problem, considered dynamics viscosity, heat, diffusivity as temperature-dependent variables. model, which governed by system PDEs, accomplishes Optimal Homotopy Analysis Method (OHAM). limiting sense, validation numerical results...

This study examines the properties of tetra hybrid nanofluids (HNF 4 ) using Blasius Rayleigh- Stokes time-dependent variable model to aid solar automobile engineers. It explores behavior under various conditions, focusing on effects viscosity and thermal conductivity. Copper (Cu), Zirconium dioxide (ZrO2), Aluminium Oxide (Al2O3), Iron (Fe3O4) nanoparticles are studied with ethylene glycol (EG) as base fluid. The governing PDEs were transformed into non- dimensional equations, resulting in...

The present study is designed to model the combustible materials of two vertical plates with Arrhenius energy and exothermic chemical reaction. magnetohydrodynamics fluid considered experience an reaction inside channel. Additional effects incorporated novelty are rheological Casson term variable electrical conductivity. has transformed appropriately its dimensionless form using similarity renovation Solution numerically obtained Chebyshev collocation scheme. influences controlling...

The global threat of environmental degradation from harmful waste discharge is evident, leading to unusual diseases and natural disasters. Some these toxic emissions result human activities, such as the incomplete combustion hydrocarbons. As such, this study aims explore analysis electromagnetic radiative heat sources on tangential hyperbolic fluid under Arrhenius kinetic with convective cooling. transformed momentum equations are solved using a rigorous computational approach called...

This study analyses the properties of ternary and tetra hybrid nanofluids using Blasius Rayleigh–Stokes time dependent variable model. The aim is to provide a model for solar aeronautical engineering. focuses on behavior under various conditions effects viscosity thermal conductivity their performance. Copper (Cu), Zirconium dioxide (ZrO2), Aluminium Oxide (Al2O3) Iron (Fe3O4) are four nanoparticles examined in this with mixture ethylene glycol (EG) as base fluid. governing Partial...

Sequel to all the published facts on hydrothermal of pure water a permeable expanding/contracting surface with thermodynamic irreversibilities convey iron (III) oxide and copper hybrid nanoparticles as applicable in industry engineering, nothing is known about importance viscous dissipation Joule heating. The current paper addresses natural convective flow water, / nanofluid and-hybrid nanofluid, (a novel advanced composited nanoparticles) induced by non-linearly stretching sheet velocity...

This study investigates the effect of a Riga plate on flow characteristics Casson hybrid nanofluid through stretching cylinder embedded in porous medium presence an exponential heat source and thermal radiation. model is used toexplore potential applications this analysis fields cancer treatment wound healing. The governing partial differential equations are converted into system nonlinear ordinary using suitable similarity transformations. (PDEs) were reduced to (ODEs) variables, transfer...

Entropy generation minimization is a method that helps to improve the efficiency of real processes and devices. This study investigates heat transfer in an electrically conducting Casson fluid flow between parallel plates under influence thermal radiation convective boundary conditions. The thermodynamics first second laws were employed examine problem. present provides fast convergent on finite plates, namely Optimal Homotopy Analysis (OHAM) Collocation Method (CM) are used analyzes flow,...

The magnetohydrodynamic (MHD) chemically reactive of Casson non-Newtonian nanofluid flow on a two-dimensional incompressible steady from stretched sheet in porous quiescent medium with buoyancy effect is investigated numerically. Additional effects included the originality model are applied magnetic field and solar radiation effect. Chebyshev collocation method (CCM) was used to solve ordinary differential equations (ODEs) MATHEMATICA 11.3 software. present tables graphs show performance...

In various fields such as engineering, nanotechnology, and biomedical sciences, the study of non-Newtonian nanofluid flow with heat generation is becoming increasingly important. However, it challenging to accurately model flows due their complex behavior slip effects at fluid-solid interface. This research investigates impact first second-order conditions on transfer properties a using power law describe fluid's numerical methods solve resulting equations. To determine influence parameters...

This study examines the thermal mechanism of magneto-radiated hybrid nanofluids, composed aluminium oxide (Al₂O₃), iron (II, III) (Fe₃O₄), and copper II (CuO) suspended in blood, with an emphasis on their application biomedical engineering, The makes use a three-dimensional surface model to analyze heat transfer characteristics behavior ternary nanofluid under inclined magnetic fields radiative conditions. incorporation Fe₃O₄ nanoparticles enhanced conductivity medium responsiveness fields,...

Abstract Thermal explosions in reactive flows present an important risk to industrial engineering systems, where uncontrolled exothermic reactions can compromise safety and operational integrity. This study investigates the theoretical solutions related thermal runaway heat transport a branch-chain bifurcation scenario influenced by hydromagnetic Powell–Eyring fluid flow. By incorporating factors such as current density variable properties, we aim enhance safety, reliability, efficiency of...