Bioconvection Maxwell nanofluid flow over a stretching cylinder influenced by chemically reactive activation energy surrounded by a permeable medium

The role of nanofluids in the development many electronic devices at industrial level is very significant. This investigation describes thermal exploration for a bioconvective flow Maxwell nanoparticles over stretching and revolving cylinder placed porous medium. fluid contact with chemically reactive activation energy. swirling induced by rotary cylinder. magnetic effect constant strength B0 practiced to system combination thermally radiative effects heat source/sink controlling upon system. thermophoretic Brownian motion characteristics, due nanofluid flow, are captured implementing Buongiorno model. central focus this study explore mass transfer problem accompanied motile microorganisms. governing equations have been converted dimensionless form similar variables, homotopy analysis method (HAM) has then applied solution. It concluded that decays escalation Maxwell, porosity, parameters, Forchheimer bioconvection Rayleigh numbers, while upsurges augmenting values Buoyancy factor. With increasing number, radiation factors upsurge profiles decline concentration profiles. Moreover, density microorganisms declines expansion Peclet number. range id="m2">η taken from 0 seven get convergence graph.