LAUSR

The target of current research is to discuss the induced magnetic field stagnation point flow of carbon nanoliquids influenced by Riga surface with Thomson and Troian slip condition. The heat transfer phenomenon is manipulated over Cattaneo–Christov heat flux model with thermal stratification and heat generation or absorption. The flow model is transferred into nondimensionless form via convenient transformation. The numerical outcome of nonlinear complex equations is made by using bvp4c technique. The effects of emerging parameters on the velocity, temperature and concentration distribution are deliberated graphically. The velocity profile enhances with velocity ratio parameter and modified Hartman number. Further, the solid volume fraction enhances the temperature distribution and Sherwood number.