LAUSR

Abstract Fluid flow through micro/nanofluidics is of utmost importance in analyzing mechanical, biological and medical systems. Biological liquids are often electrolytes that produce spontaneous electrokinetic effects when flowing through pores and channels. The streaming potential which is resultant of this electrokinetic phenomenon drives the ions in the channel to move in the direction opposite to the pressure-driven flow and causes a resistance against fluid flow along the channel. It is simply similar to the case when the viscosity of the fluid is slightly increased. It is expected to have a lower flow rate in the presence of the electroviscous effects; however, understanding of these effects on thermal transport characteristics would be interesting. The present study attempts to present a theoretical investigation of the electroviscous effects on heat transfer in nanofluidics based on continuum fluid mechanics while boundary slip is assumed on the walls. Results show that the presence of electroviscous effects will remarkably enhance the heat transfer rate.