Litcius/Paper detail

Reverse capillary trapping and self-removal of non-aqueous fluid from dead-end structures by nanoparticle suspension

Wenhai Lei, Xukang Lu, Guang Yang, Shervin Bagheri, Moran Wang

2025Journal of Fluid Mechanics6 citationsDOI

Abstract

We report an anomalous capillary phenomenon that reverses typical capillary trapping via nanoparticle suspension and leads to a counterintuitive self-removal of non-aqueous fluid from dead-end structures under weakly hydrophilic conditions. Fluid interfacial energy drives the trapped liquid out by multiscale surfaces: the nanoscopic structure formed by nanoparticle adsorption transfers the molecular-level adsorption film to hydrodynamic film by capillary condensation, and maintains its robust connectivity, then the capillary pressure gradient in the dead-end structures drives trapped fluid motion out of the pore continuously. The developed mathematical models agree well with the measured evolution dynamics of the released fluid. This reversing capillary trapping phenomenon via nanoparticle suspension can be a general event in a random porous medium and could dramatically increase displacement efficiency. Our findings have implications for manipulating capillary pressure gradient direction via nanoparticle suspensions to trap or release the trapped fluid from complex geometries, especially for site-specific delivery, self-cleaning, or self-recover systems.

Topics & Concepts

Capillary actionSuspension (topology)Materials scienceAqueous suspensionAqueous solutionTrappingNanoparticleChemical engineeringDead endMechanicsNanotechnologyFlow (mathematics)Composite materialChemistryPhysicsHomotopyPhysical chemistryEngineeringMathematicsPure mathematicsBiologyEcologyLattice Boltzmann Simulation StudiesPickering emulsions and particle stabilizationEnhanced Oil Recovery Techniques