Transportation of Marangoni convection with dust particles random motion in flow of hybrid nanomaterials

Owing to the magnified thermal practices, the nanoparticles pronounced novel applications in many engineering processes and industrial systems such as thermal devices, electronic cooling systems, microprocessors, radiators, micro-electromechanical system, and heat exchangers. The prime motivation for performing this investigation is to pronounce the thermal reflection of hybrid nanofluid subject to the water base material. The particles of copper and silver metals are taken into account for the thermal analysis. The spherical shape of nanoparticles and dust material is assumed. The additional consequences of magnetic force and porous saturated implication are also considered. The shooting numerical approach is directed for the simulation process. The hybrid nanofluid characteristics are listed. The validity conformation against obtained numerical data is carried out by making the comparative analysis. The physical consideration for flow parameters is accessed via graphical approach. The observations reveal that change in the velocity and thermal prospective is more dominant for hybrid nanofluid model in contrast to the dust phase model. The hybrid nanofluid velocity for the silver and copper nanoparticles grows for the higher dust particles mass concentration.