Enhanced heat transportation for bioconvective motion of Maxwell nanofluids over a stretching sheet with Cattaneo–Christov flux

The main aim of this work is to study the thermal conductivity base fluid with mild inclusion nanoparticles. We perform numerical for transportation Maxwell nanofluids activation energy and Cattaneo–Christov flux over an extending sheet along mass transpiration. Further, bioconvection microorganisms may support avoiding possible settling nanoentities. formulate theoretical as a nonlinear coupled boundary value problem involving partial derivatives. Then ordinary differential equations are obtained from leading help appropriate similarity transformations. obtain results by using Runge–Kutta fourth-order method shooting technique. effects various physical parameters such mixed convection, buoyancy ratio, Raleigh number, Lewis Prandtl magnetic parameter, transpiration on bulk flow, temperature, concentration, distributions presented in graphical form. Also, skin friction coefficient, Nusselt Sherwood motile density number calculated form tables. validation procedure confirmed through its comparison existing results. computation carried out suitable inputs controlling parameters.