Effect of natural convection on 3D MHD flow of MoS2-GO/H2O via porous surface due to multiple slip mechanisms

The theme of this work is to examine the magnetized flow behaviour of hybrid nanofluid containing molybdenum disulphide (MoS2) and graphene oxide (GO) nanoparticles subject to multiple slip mechanisms, natural convection and chemical reaction of mth order. The working hybrid nanofluid is prepared by an amalgamation of nanoparticles, i.e. MoS2 and GO and conventional fluid (H2O). The existing equations of the model were solved by the techniques, i.e. shooting and bvp4c. To validate our codes, the comparison was presented by previous research. Here, we observed that, with an increase in thermal slip parameter values, only the thermal field profiles of MoS2-GO/H2O regularly depreciated. Moreover, when there was augmentation in velocity slip parameter, temperature and concentration functions rose, while both velocity outlines of MoS2-GO/H2O fluid declined. Furthermore, the velocity functions of MoS2-GO/H2O augmented and the concentration function declined with an increase in natural convection parameter values.

Automated summary

The magnetized flow behaviour of a hybrid nanofluid containing molybdenum disulphide (MoS2) and graphene oxide (GO) nanoparticles, subject to multiple slip mechanisms, natural convection and chemical reaction, is examined in this study. The hybrid nanofluid is prepared by combining MoS2, GO, and a conventional fluid (H2O). The equations of the model are solved using shooting and bvp4c techniques, and are validated against previous research. The study shows that an increase in thermal slip parameter values leads to a depreciation in the thermal field profiles of MoS2-GO/H2O. Additionally, an increase in velocity slip parameter results in an increase in temperature and concentration functions, while the velocity outlines of the MoS2-GO/H2O fluid decrease. Furthermore, an increase in natural convection parameter values leads to an augmentation in the velocity functions and a decline in the concentration function of MoS2-GO/H2O.