Path selection during wormhole growth

Growth of wormholes in porous media can lead to self-organization of flow networks with an overwhelming geometric complexity. Despite decades of study, the mechanism by which a dominant wormhole develops its path during growth remains elusive. Here we show that the trajectory of a growing wormhole can be predicted by identifying the flowpath with a so-called minimum cumulative surface. Our theoretical analysis indicates that the cumulative surface determines the position of the dissolution front. We then show, using numerical simulation based on greyscale nanotomography data, that the tip of an advancing pore always follows the migration of the most far reaching dissolution front. Finally, we show the good accord between theory and the observation with in situ microtomography. Our result suggests that wormholing is a deterministic process rather than, as classical theories imply, a stochastic one that can only be analysed statistically. Our results shed new light on engineering of artificial flow systems by exploiting self-organization in natural porous materials.