Mixed convection hybrid nanoliquid flow over an exponentially stretching rough (smooth) surface with the impacts  of homogeneous–heterogeneous reactions

Patil, P.M.; Benawadi, Sunil

doi:10.1002/htj.22268

Cited by 7 publications

(2 citation statements)

References 33 publications

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“…The boundary layer flow analysis in the presence of surface and homogeneous reactions can be found in Mahdy 16 , Mondal and Bharti 17 , Kameswaran et al 18 , Abbas et al 19 , Bachok et al 20 , and Patil and Benawadi. 21 Sheremet et al 22 have studied numerically the influence of chemical reaction in a chamber filled with nanosuspension using Tiwari and Das' model. Umavathi et al [23][24][25] have investigated the mixed convection flow under chemical reaction effects.…”

Section: Introductionmentioning

confidence: 99%

“…Animasaum et al 15 have investigated the homogeneous and surface reactions in a flow of viscoelastic fluid by considering the unequal diffusivity of chemical species. The boundary layer flow analysis in the presence of surface and homogeneous reactions can be found in Mahdy 16 , Mondal and Bharti 17 , Kameswaran et al 18 , Abbas et al 19 , Bachok et al 20 , and Patil and Benawadi 21 . Sheremet et al 22 have studied numerically the influence of chemical reaction in a chamber filled with nano‐suspension using Tiwari and Das' model.…”

Section: Introductionmentioning

confidence: 99%

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Homogeneous and heterogeneous reactions in the mixed convection flow of hybrid nanofluid over a slender cylinder

Patil

Benawadi

Tonannavar

et al. 2022

Asia-Pacific J Chem Eng

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This article is about the study of homogeneous and heterogeneous reactions in the mixed convection flow of hybrid nanofluid over a moving vertical slender cylinder. It is based on the considerations of unequal diffusivity of chemical species and the numerical solutions from the nonsimilar approach. This study has found applications in many chemically reacting processes, including the processes in the biochemical systems, combustion, and catalysis. Numerically approximate solutions to a set of equations, which govern the flow, temperature, and concentrations of the chemical species with prescribed boundary constraints, are obtained by utilizing the implicit finite-difference scheme aided by the quasi-linearization technique. The impacts of several relevant parameters on various profiles and gradients are discussed with the aid of graphs and tables. From the results, the skin friction coefficient and rate of heat transport are pronounced to be more for hybrid nanofluid than nanofluid.The strength of homogeneous reaction on species concentration is found to be fewer than the heterogeneous reaction. The streamwise coordinate (nonsimilar variable) is more favorable to the concentration of autocatalyst than to the reactant concentration.

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