Mixed convection Casson polymeric flow from a nonlinear stretching surface with radiative flux and non‐Fourier thermal relaxation effects: Computation with CSNIS

The present work aims to study the influence of variable thermal conductivity in generalized thermoelastic solid with microstretch within the framework of the Green‐Naghdi theory. The analytical methodology is adopted for obtaining exact expressions of displacement components, stresses, couple stresses, micro stress distribution and temperature distribution. The effect of variable thermal conductivity is illustrated graphically in two and three dimensions for the above physical quantities by taking different values of thermal conductivity.

Section: Introductionmentioning

confidence: 99%

“…Shahid et al. [32] examined the laminar viscoplastic boundary layer flow and mixed convective heat transfer over a power‐law nonlinear stretching surface.…”

Section: Introductionmentioning

confidence: 99%

Variable thermal conductivity in context of Green‐Naghdi theory of thermo‐microstretch solids

Ailawalia,

Priyanka,

Marin

et al. 2024

Integrated intelligence of inverse multiquadric radial base neuro‐evolution for radiative MHD Prandtl–Eyring fluid flow model with convective heating

Butt,

Ahmad,

Shoaib

et al. 2024

In this communication, a new stochastic numerical paradigm is introduced for thorough scrutinization of the magnetohydrodynamic (MHD) boundary layer flow of Prandtl–Eyring fluidic model along a stretched sheet impact on thermal radiation as well as convective heating scenarios by exploiting the accurate approximation knacks of ANNs (artificial‐neural‐networks) modeling by using the inverse multiquadric (IMQ) function optimized/trained with well‐reputed global search with genetic algorithms (GAs) and local search efficacy of sequential quadratic programming (SQP), that is, ANNs‐IMQ‐GA‐SQP. The mathematical model of the Prandtl–Eyring fluid flow is portrayed in the form of PDEs and then converted in the form of a nonlinear system of ODEs by utilizing suitable similarity transformation to calculate/analyze the solution dynamics. The kinematic and thermodynamic properties of MHD Prandtl–Eyring fluid flow are examined/observed by varying the sundry physical parameters. The obtained intelligent computing designed solver‐based numerical results are consistently found in good agreement with reference results obtained through the Adams numerical technique. First and second‐order cumulant‐based statistical assessments are extensively exploited to endorse trustily the efficacy of ANNs‐IMQ‐GA‐SQP solver based on exhaustive simulations for the Prandtl–Eyring fluidic system.

Effects of Al₂O₃‐Cu‐H₂O hybrid nanofluid with Soret and Dufour on mixed convection flow over a curved surface

Kenchogonahalli Ramu,

Pobbathy Aswathanarayana Setty,

Magge Venkatachala Iyengar

et al. 2024

Hybrid nanofluids, which have a higher effective thermal conductivity than both regular fluids and nanofluid, are essential in industrial, biomedical, and engineering applications. Blood flow via an artery is a useful application for the investigation of hybrid nanofluids (Cu and Al2O3). Graphs have been used to discuss the effects of flow elements on velocity, temperature, and concentrations where values have been tabulated. A hybrid combination made up of copper and aluminum oxide with volume percentages in the range of 0.01–0.2. The Dufour effect was lessened, the volume proportion of copper was reduced, and the heat transmission rate was successfully increased. Maximum rates of heat, mass, and skin friction transmission would result from stronger mixed convection. This significant initial study will provide engineers and scientists the knowledge on effective management of fluid flow while optimizing the connected complex systems. Before being written and solved with the help of Maple software, the flow control equations were simplified. Figures present the main findings of the study, including the influence of several physical parameters. The effects of physical factors on the flow distributions are illustrated in tables and figures. Water is employed as the basic fluid, and a combination of copper and alumina nanoparticle is used as the study material to investigate the heat and mass phenomena brought by the Dufour and Soret effect. Surface thermal efficiency is influenced by the Soret factor, whereas surface mass transfer is constrained by the Dufour effect.