Mechanistic study of nanoparticles�surfactant foam flow in etched glass micro-models
This study was conducted in order to identify the pore-level mechanisms controlling the nanoparticles�surfactant foams flow process and residual oil mobilization in etched glass micro-models. The dominant mechanism of foam propagation and residual oil mobilization in water-wet system was identifie...
| Main Authors: | Yekeen, N., Manan, M.A., Idris, A.K., Samin, A.M., Risal, A.R. |
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| Format: | Article |
| Institution: | Universiti Teknologi Petronas |
| Record Id / ISBN-0: | utp-eprints.20935 / |
| Published: |
Taylor and Francis Inc.
2018
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| Online Access: |
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85031800827&doi=10.1080%2f01932691.2017.1378581&partnerID=40&md5=061534ee16916717912b70928014e016 http://eprints.utp.edu.my/20935/ |
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| Summary: |
This study was conducted in order to identify the pore-level mechanisms controlling the nanoparticles�surfactant foams flow process and residual oil mobilization in etched glass micro-models. The dominant mechanism of foam propagation and residual oil mobilization in water-wet system was identified as lamellae division and emulsification of oil, respectively. There was inter-bubble trapping of oil and water, lamellae detaching and collapsing of SDS-foam in the presence of oil in water-wet system and in oil-wet system. The dominant mechanisms of nanoparticles�surfactant foam flow and residual oil mobilization in oil-wet system were the generation of pore spanning continuous gas foam. The identified mechanisms were independent of pore geometry. The SiO2-SDS and Al2O3-SDS foams propagate successfully in water-wet and oil-wet systems; foam coalescence was prevented during film stretching due to the adsorption and accumulation of the nanoparticles at the gas�liquid interface of the foam, which increased the films� interfacial viscoelasticity. © 2017 Taylor & Francis. |
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