Review on physical and chemical factors affecting fines migration in porous media

•Critical review of current understanding on key factors affecting fines migration.•Deviation of salinity-related colloid release observations from DLVO predictions.•New hypothesis on colloid attachment-detachment hysteresis proposed.•Discussion on quantification of anomalous salinity effect on adhe...

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Bibliographic Details
Published in:Water research (Oxford) 2022-05, Vol.214, p.118172-118172, Article 118172
Main Authors: Yang, Yulong, Yuan, Weifeng, Hou, Jirui, You, Zhenjiang
Format: Article
Language:English
Subjects:
Attachment-detachment hysteresis
Delayed release
Fines migration
Ionic strength
Maximum retention concentration
Surface heterogeneity
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Summary:•Critical review of current understanding on key factors affecting fines migration.•Deviation of salinity-related colloid release observations from DLVO predictions.•New hypothesis on colloid attachment-detachment hysteresis proposed.•Discussion on quantification of anomalous salinity effect on adhesion force. Permeability reduction and formation damage in porous media caused by fines (defined as unconfined solid particles present in the pore spaces) migration is one of the major reasons for productivity decline. It is well accepted that particle detachment occurs under imbalanced torques arising from hydrodynamic and adhesive forces exerted on attached particles. This paper reviewed current understanding on primary factors influencing fines migration as well as mathematical formulations for quantification. We also introduced salinity-related experimental observations that contradict theoretical predictions based on torque balance criteria, such as delayed particle release and attachment-detachment hysteresis. The delay of particle release during low-salinity water injection was successfully explained and formulated by the Nernst-Planck diffusion of ions in a narrow contact area. In addition to the widely recognized explanation by surface heterogeneity and the presence of low-velocity regions, we proposed a hypothesis that accounts for the shifting of equilibrium positions, providing new insight into the interpretation of elusive attachment-detachment hysteresis both physically and mathematically. The review was finalized by discussing the quantification of anomalous salinity effect on adhesion force at low- and high-salinity conditions. [Display omitted]
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2022.118172