Counter-intuitive reduction of thermal contact resistance with porosity: A case study of polymer electrolyte membrane fuel cells

The present study reveals that the conventional notion that thermal contact resistance increases with porosity does not necessary hold. It is proved through a mechanistic robust model that, under specific circumstances, the porosities of two contacting bodies attain a critical value beyond which the contact resistance counter-intuitively drops. The model focuses on micro porous layers (MPLs) coated on gas diffusion layers (GDLs) of polymer electrolyte membrane fuel cells (PEMFCs) and is validated with the MPL-GDL thermal contact resistance measured over a range of pressure. The counter-intuitive reduction of the contact resistance with porosity can find important applications in energy conversion systems such as PEMFCs and batteries where contact resistance plays a major role in ohmic loss and heat management. This game changing finding can lead to improving mass and heat transfer, diffusivity and permeability of porous materials by increasing the porosity without any compromise on contact resistance or ohmic loss. The present cutting-edge research can also open new avenues for fuel cell and any other manufacturers to develop state-of-the-art materials with higher porosities but lower contact resistances, which are currently not available in the market. Copyright (C) 2016, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved.