Significance of heat and mass transport in peristaltic flow of Jeffrey material subject to chemical reaction and radiation phenomenon through a tapered channel

Abstract Using mathematical modeling and computational analysis, this study aims to examine the peristaltic blood flow of a non-Newtonian material in tapered channel with radiative heat flux response mechanisms. By utilizing long-wavelength approximation, ignoring wave number, performing under conditions low Reynolds closed form solutions for velocity, temperature, concentration fields are achieved. Several governing parameters their effects on system were analyzed, relevant diagrams provided. Increasing Biot Jeffrey material, thermal radiation parameter mass transfer mechanism increases velocity profile. When source/sink number increase, temperature profile improves. The resultant distributions enhanced when radiation, chemical processes all raised. We observe that pressure rate decreases three pumping zones Grashof rise. This is because affected by transmission. increase results slower than Prandtl increases. Soret Schmidt raised, coefficient also rises. rate, however, as reaction findings presented have interesting implications other aspects human physiology. preponderance organs permeable. Furthermore, fluids render location natural boundaries uncertain. model can be used derive predictions about behavior various systems. For cancer treatment biological systems, includes nanoparticles, viscosity dissipation, rotation holds much promise. Model development incorporated Soret–Dufour analysis digestive system.