The thermodynamics of aggregates of solid particles immersed in a percolating liquid is revisited. The expressions of the driving forces involve shape factors which are functions of the liquid volume fraction, u, and average particle coordination, n c . A model considering arbitrary, isotropic interface energies, γ sl and γ ss , is proposed for expressing these functions. The paper discusses the bearings of the model for the case of a dihedral angle ψ=0. The driving force for the absorption of liquid increases both with decreasing u and with decreasing n c . It is found that n c tends to decrease spontaneously. The model is applied to: (1) the prediction of liquid migration in bi-materials assemblies, (2) the computation of the relationships between spatial distributions of u, n c , and particle size in gradient materials, and (3) the analysis of the distribution of u resulting from liquid migration induced by gravity.