Dynamics of convective slippery constraints on hybrid radiative Sutterby nanofluid flow by Galerkin finite element simulation

Bouslimi, Jamel; Alkathiri, Ali A.; Alharbi, Abdulaziz N.; Jamshed, Wasim; Eid, Mohamed R.; Bouazizi, Mohamed Lamjed

doi:10.1515/ntrev-2022-0070

Cited by 27 publications

(9 citation statements)

References 87 publications

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“…Masayebidarched et al 19 performed theoretical analysis for the thermal enhancement in fluid with hybrid nanoparticles. Similar works published on the role of hybrid nanoparticles on thermal enhancement can be seen in references 20 – 32 .…”

Section: Introductionsupporting

confidence: 71%

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

Hafeez

Krawczuk

Shahzad

et al. 2022

Sci Rep

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The present study probed the creation of heat energy and concentrating into Newtonian liquids across vertical 3D-heated plates. The role of the Soret and Dufour theories in concentrating and energy formulas is discussed. The role of hybrid nanoparticles is introduced to illustrate particle efficiency in terms of solute and thermal energy. It is removed a viscous dissipation process and a changing magnetic field. The proposed approach is motivated by the need to maximize solute and thermal energy uses in biological and industrial domains. The constructed system of (partial differential equations) PDEs includes concentration, momentum, and thermal energy equations within various thermal characteristics. Transformations are used to formulate the system of (ordinary differential equations) ODEs for solution. To assess various features vs various variables, a Galerkin finite element approach is used. Motion into nanoscale components is shown to be smaller than motion into hybrid nanoparticles. Furthermore, fluctuations in heat energy and solute particle counts are seen in relation to changes in Soret, Eckert, magnetic, and Dufour numbers. The basic finding is that the generation of thermal energy for hybridized nanomaterials is much higher.

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Section: Introductionsupporting

confidence: 71%

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

Hafeez

Krawczuk

Shahzad

et al. 2022

Sci Rep

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show abstract

“…On the one hand, the validity of the computational technique was tested by comparing the current method's performance to the available data on heat transfer rate in Refs. (Hussain et al, 2022b;Bouslimi et al, 2022). Table 3 demonstrates the consistent comparison found across the investigations.…”

Section: Code Authenticationsupporting

confidence: 62%

“…Bouslimi et al (Hussain et al, 2022b) Hussain (Bouslimi et al, 2022) Present Results The illustration of the non-Newtonian Powell-Eyring fluid term (β 2 ) on the model profiles (flow velocity, temperature, and entropy) against a rising stream term (β 2 ) were depicted in Figures 5A,B,C. The velocity profile (Figure 5A) is decreased as the material term increases due to the material term shear being induced by infinite fluid viscosity.…”

Section: P Rmentioning

confidence: 66%

Quadratic regression estimation of hybridized nanoliquid flow using Galerkin finite element technique considering shape of nano solid particles

Rahman

Jamshed

et al. 2022

Front. Energy Res.

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Because of its multivariate particle suspension approach, the developing class of fluid has a better level of stability as well as increased heat transfer. In this regard, hybrid nanofluid outperforms ordinary fluid and even well-known nanofluid. In a slick environment, we investigate its fluidity and heat transfer qualities. Nano-leveled particle morphologies, porousness materials, variable thermal conductivity, slippage velocity, and thermal radiative effects are all being studied. The Galerkin finite element method is a numerical methodology for numerically solving the governing equations (G-FEM). For this analysis, a Powell-Eyring hybrid nanofluid (PEHNF) flowing via a permeable stretchable surface is used, which comprises two types of nanoparticles (NP), copper (Cu), and titanium alloy (Ti6Al4V) dispersed in sodium alginate (C6H9NaO7). The heat transfer ratio of PEHNF (Ti6Al4V-Cu/C6H9NaO7) remained much greater than that of conventional nanofluids (Cu-C6H9NaO7), with a range of 43%–54%. When lamina particles are present, the thermal conductivity of the boundary layer increases dramatically, while spherical nanoparticles have the lowest thermal conductivity. As nanoparticles are added under their fractional sizes, radiative heat conductance, and flexible heat conductance, the system’s entropy increases. The flow system’s ability to transport mass decreases when molecule diffusivity decreases dramatically. This is theoretically related to a rise in Schmidt number against molecular diffusivity.

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“…The inside geometric PTSC is illustrated in Figure 1. The diminished conditions from Bouslimi et al 74 were utilized for the progression of gooey Sutterby nanofluid by standard limit layer approximations including inclined MHD, thermal radiation, variable thermal conductivity, and inclined joule heating impacts which are outlined as follows:…”

Section: Flow Model Formulationsmentioning

confidence: 99%

Computational technique of thermal comparative examination of Cu and Au nanoparticles suspended in sodium alginate as Sutterby nanofluid via extending PTSC surface

Jamshed

Safdar

Rehman

et al. 2022

Journal of Applied Biomaterials & Functional Materials

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Current research underscores entropy investigation in an infiltrating mode of Sutterby nanofluid (SNF) stream past a dramatically expanding flat plate that highlights Parabolic Trough Solar Collector (PTSC). Satisfactory likeness factors are utilized to change halfway differential conditions (PDEs) to nonlinear conventional differential conditions (ODEs) along with relating limit requirements. A productive Keller-box system is locked in to achieve approximated arrangement of decreased conventional differential conditions. In the review, two sorts of nanofluids including Copper-sodium alginate (Cu-SA) and Gold-sodium alginate (Au-SA) are dissected. Results are graphically plotted as well as talked about in actual viewpoints. As indicated by key discoveries, an improvement in Brinkmann, as well as Reynolds number, brings about expanding the general framework entropy. Sutterby nanofluid boundary improves heat rate in PTSC. Additionally, Copper-sodium alginate nanofluid is detected as a superior thermal conductor than Gold-sodium alginate nanofluid. Further to that, the reported breakthroughs are beneficial to updating extremely bright lighting bulbs, heating and cooling machinery, ﬁber required to generate light, power production, numerous boilers, and other similar technologies.

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Dynamics of convective slippery constraints on hybrid radiative Sutterby nanofluid flow by Galerkin finite element simulation

Cited by 27 publications

References 87 publications

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

Quadratic regression estimation of hybridized nanoliquid flow using Galerkin finite element technique considering shape of nano solid particles

Computational technique of thermal comparative examination of Cu and Au nanoparticles suspended in sodium alginate as Sutterby nanofluid via extending PTSC surface

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