Unstable drainage dynamics during multiphase flow across capillary heterogeneities

TL;DR

This study employs advanced 4D synchrotron X-ray imaging to investigate how pore-scale heterogeneities in layered sandstone influence unstable and unpredictable gas-brine drainage dynamics, revealing the significant impact of structural variability on flow behavior.

Contribution

It demonstrates that pore-scale heterogeneity can cause flow instability and variability, emphasizing the importance of probabilistic models for multiphase flow in porous media.

Findings

Heterogeneity in pore connectivity acts as a capillary barrier.

Flow pathways are highly sensitive to upstream invasion variations.

Breakthrough times vary by up to a factor of four.

Abstract

We use novel, fast 4D Synchrotron X-ray imaging with large field-of-view to reveal pore- and macro-scale drainage dynamics during gas-brine flow through a layered sandstone rock sample. We show that a single centimetre-scale layer, similar in pore size distribution to the surrounding rock but with reduced connectivity, temporarily inhibits and redirects gas flow, acting as a capillary barrier. Subtle variations in gas invasion upstream of the barrier lead to different downstream migration pathways over repeated experiments, resulting in unstable and unpredictable drainage behaviour, with breakthrough times varying by up to a factor of four. The results show that heterogeneity in pore-scale connectivity can amplify variability in macroscopic flow, challenging deterministic assumptions in existing continuum models. By linking structural heterogeneity to flow instability, this work underscores the need for probabilistic modelling approaches in multiphase flow and highlights broader implications for managing fluid transport in natural and engineered porous systems.