Mixed convection radiated flow of Jeffery-type hybrid nanofluid due to inclined oscillating surface with slip effects: a comparative fractional model

Abstract

A fractional model is developed for addressing the radiative thermal flow of hybrid nanofluid in presence of Jeffrey base material. The characterization of hybrid nanofluid is presented by utilizing the copper, aluminum oxide and titanium dioxide nanoparticles. The fluctuation in the heat and mass transportation phenomenon is observed in presence of mixed convection and magnetic force implementation. The inclined oscillating plate induced the flow subject to the slip effects and porous space. The fluctuation in the temperature is observed at different time instants. The fundamental laws are incorporated to model the problem and later on the dimensionless system of the fractional problem has been obtained via appropriate variables. The fractional simulations with help of Caputo–Fabrizio (CF) and Atangana–Baleanu (AB) techniques. The comparative aspect of both AB and CF fractional operators in view of flow parameters is workout. The exact solution for the obtained analytical expressions is successfully suggested. Moreover, some limiting cases for the oscillating flow have also been addressed. The numerical variation for heat and mass transfer phenomenon by using both fractional techniques and different Laplace inverse operators is observed.