The aim of the present paper is to analyze the second law of thermodynamics in term of entropy generation in electrically conducting viscous incompressible natural convective fluid flow past an infinite vertical porous plate in the presence of thermal radiation, transverse magnetic field and heat source with constant suction. The effects of various fluid parameters on velocity and temperature field are discussed. In addition, the entropy generation due to viscous dissipation, fluid friction and magnetic field is analyzed. It is concluded that the entropy of the flow system near the plate can be regulated by high intensity of applied magnetic field and heat source, and reverse behavior is observed far away from the plate.

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Entropy Generation Heat Source Thermal Radiation