English

Modeling Ostwald Ripening Dynamics in Porous Microstructures

Fluid Dynamics 2026-04-09 v1 Geophysics

Abstract

Partially miscible ganglia trapped in a porous medium evolve through Ostwald ripening, driven by differences in interfacial curvature. In practice, ganglia can span multiple pores and undergo discrete capillary events - invasion, snap-off, retraction, fragmentation, coalescence, and dislocation - that alter their topology and induce local flow. Existing pore-network models (PNMs) for ripening are limited to single-pore ganglia, assume idealized pore shapes, and operate under quasi-static conditions that preclude flow. We present an image-based pore-network model (iPNM) that removes these limitations. Unlike existing PNMs, iPNM requires no idealization of pore shapes, as the effect on capillarity is encoded locally in curvature-saturation curves computed via the pore-morphology method. iPNM couples two-phase flow, solute transport, and Ostwald ripening within a unified framework. We first verify iPNM against a prior quasi-static PNM, then validate it against recent high-resolution microfluidic experiments of hydrogen ripening in a sandstone-patterned micromodel over 15-24 days at 40C and 80C. Good agreement is obtained without adjustable parameters. Comparison with a continuum model shows that while macroscopic saturation is captured by both approaches, iPNM uniquely resolves population statistics, individual ganglion curvatures, and pre-equilibrium ripening dynamics within a representative elementary volume. Its computational efficiency over direct numerical simulation makes it suitable for guiding the development of improved theories of ripening in confined geometries.

Cite

@article{arxiv.2604.06581,
  title  = {Modeling Ostwald Ripening Dynamics in Porous Microstructures},
  author = {Md Zahidul Islam Laku and Mohammad Salehpour and Tian Lan and Benzhong Zhao and Yashar Mehmani},
  journal= {arXiv preprint arXiv:2604.06581},
  year   = {2026}
}
R2 v1 2026-07-01T11:58:30.906Z