Direct Alcohol Fuel Cells (DAFCs) have the potential to compete with current battery technology due to the high energy density of the alcohol fuels. A major limitation to these fuel systems is "blinding" where CO2 gas pushes through the porous gas diffusion layer (GDL) forming bubbles in the flow channels inhibiting fuel delivery to the catalyst layer. We report here measurements of material wettability, advancing and receding contact angles, and gas bubble formation to describe multiphase transport processes relevant to DAFCs. Carbon paper and carbon cloth have large differences in the receding contact angles (theta(R,paper) = 85 degrees, theta(R,cloth) = 120 degrees), which result in differences in bubble growth and detachment from the GDL surface. Bubbles on carbon paper were similar to 40-50% smaller than on carbon cloth. The gas pressure to push gas through the GDL was 50-80% greater for carbon paper. The geometry of the flow channel also played a major role in confining bubble growth. The permeable nature of the GDL resulted in lateral transport of gas to existing bubbles. This fundamental understanding of transport processes suggested an electrode design with dedicated gas removal channels that could enable a DAFC to operate without bubble formation. (C) 2013 Elsevier Ltd. All rights reserved.