Influences of radiative heat transfer on hydromagnetic hybrid nanofluid flow through two rotating surfaces

This study explores the growth of heat transfer rate for hybrid nanofluid-flow through two rotary plates fixed parallel. For improvement thermal conductivity nanoparticles Cu and graphene oxide have dispersed in water. The fluid-flow has been influenced by radiation. Magnetic effects with strength, B0, employed normal direction plates. set equations that controlled system shifted to dimension-free form employing suitable variables. resultant solved HAM. It revealed this work upsurge values magnetic rotational factors linear velocity retarded while micro-rotational upsurge. Intensification volumetric fractions results retardation fluid motion all directions flow profiles. Thermal profiles are also sup?ported augmenting radiation factor. further nanofluid a better performance contrast traditional nanofluid.