In-situ observation of reactive wettability alteration using algorithm-improved confocal Raman microscopy

S. Nair; J. Gao; C. Otto; M.H.G. Duits; F. Mugele

doi:10.1016/j.jcis.2020.10.016

In-situ observation of reactive wettability alteration using algorithm-improved confocal Raman microscopy

S. Nair^*, J. Gao, C. Otto, M.H.G. Duits, F. Mugele^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Hypothesis
The wettability of complex fluids on surfaces usually depends on the adsorption of solutes to any of the constituting interfaces. Controlling such interfacial processes by varying the composition of a phase enables the design of smart responsive systems. Our goal is to demonstrate that 3D Confocal Raman Microscopy (CRM) can reveal the mechanistic details of such processes by allowing to simultaneously monitor the contact angle variation and redistribution of the chemical species involved.

Experiments
Motivated by the enhanced oil recovery process of low salinity water flooding, we studied the response of picolitre oil drops on mineral substrates upon varying the ambient brine salinity. The substrates were pre-coated with thin layers of deuterated-stearic acid (surfactant) that display salinity-dependent stability.

Findings
3D CRM imaging using a recently proposed faster ‘ai’ (algorithm-improved) mode reveals that the surfactant layer is stable at high salinities, leading to preferential oil wetting. Upon reducing the ambient brine salinity, this layer decomposes and the investigated surfaces of mica and – somewhat less pronounced – silica become more water wet. Eventually, the surfactant is found to partly dissolve in the oil and partly precipitate at the oil-water interface. We anticipate that ai-3D-CRM will prove useful to holistically study similar systems displaying reactive wetting.

Original language	English
Pages (from-to)	551-560
Number of pages	10
Journal	Journal of colloid and interface science
Volume	584
DOIs	https://doi.org/10.1016/j.jcis.2020.10.016
Publication status	Published - 15 Feb 2021

Keywords

Reactive wetting
Raman Imaging
Enhanced oil recovery
Confocal Raman microscopy
Surfactant

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Cite this

@article{fc525cd605374f1380c87bfb73bbcdd6,

title = "In-situ observation of reactive wettability alteration using algorithm-improved confocal Raman microscopy",

abstract = "HypothesisThe wettability of complex fluids on surfaces usually depends on the adsorption of solutes to any of the constituting interfaces. Controlling such interfacial processes by varying the composition of a phase enables the design of smart responsive systems. Our goal is to demonstrate that 3D Confocal Raman Microscopy (CRM) can reveal the mechanistic details of such processes by allowing to simultaneously monitor the contact angle variation and redistribution of the chemical species involved.ExperimentsMotivated by the enhanced oil recovery process of low salinity water flooding, we studied the response of picolitre oil drops on mineral substrates upon varying the ambient brine salinity. The substrates were pre-coated with thin layers of deuterated-stearic acid (surfactant) that display salinity-dependent stability.Findings3D CRM imaging using a recently proposed faster {\textquoteleft}ai{\textquoteright} (algorithm-improved) mode reveals that the surfactant layer is stable at high salinities, leading to preferential oil wetting. Upon reducing the ambient brine salinity, this layer decomposes and the investigated surfaces of mica and – somewhat less pronounced – silica become more water wet. Eventually, the surfactant is found to partly dissolve in the oil and partly precipitate at the oil-water interface. We anticipate that ai-3D-CRM will prove useful to holistically study similar systems displaying reactive wetting.",

keywords = "Reactive wetting, Raman Imaging, Enhanced oil recovery, Confocal Raman microscopy, Surfactant",

author = "S. Nair and J. Gao and C. Otto and M.H.G. Duits and F. Mugele",

note = "Funding Information: This work is part of the research program Rock-on-a-Chip with project number i40, which is partly financed by the Netherlands Organization for Scientific Research (NWO) and through the Exploratory Research (ExploRe) program of BP plc. BP Exploration Operating Company Limited is thanked for permission to publish this paper. The authors would also like to thank Shaoqiang Su for carrying out the in-situ liquid cell AFM imaging. Funding Information: This work is part of the research program Rock-on-a-Chip with project number i40, which is partly financed by the Netherlands Organization for Scientific Research (NWO) and through the Exploratory Research (ExploRe) program of BP plc. BP Exploration Operating Company Limited is thanked for permission to publish this paper. The authors would also like to thank Shaoqiang Su for carrying out the in-situ liquid cell AFM imaging. Publisher Copyright: {\textcopyright} 2020 The Author(s)",

year = "2021",

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doi = "10.1016/j.jcis.2020.10.016",

language = "English",

volume = "584",

pages = "551--560",

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AU - Nair, S.

AU - Gao, J.

AU - Otto, C.

AU - Duits, M.H.G.

AU - Mugele, F.

N1 - Funding Information: This work is part of the research program Rock-on-a-Chip with project number i40, which is partly financed by the Netherlands Organization for Scientific Research (NWO) and through the Exploratory Research (ExploRe) program of BP plc. BP Exploration Operating Company Limited is thanked for permission to publish this paper. The authors would also like to thank Shaoqiang Su for carrying out the in-situ liquid cell AFM imaging. Funding Information: This work is part of the research program Rock-on-a-Chip with project number i40, which is partly financed by the Netherlands Organization for Scientific Research (NWO) and through the Exploratory Research (ExploRe) program of BP plc. BP Exploration Operating Company Limited is thanked for permission to publish this paper. The authors would also like to thank Shaoqiang Su for carrying out the in-situ liquid cell AFM imaging. Publisher Copyright: © 2020 The Author(s)

PY - 2021/2/15

Y1 - 2021/2/15

N2 - HypothesisThe wettability of complex fluids on surfaces usually depends on the adsorption of solutes to any of the constituting interfaces. Controlling such interfacial processes by varying the composition of a phase enables the design of smart responsive systems. Our goal is to demonstrate that 3D Confocal Raman Microscopy (CRM) can reveal the mechanistic details of such processes by allowing to simultaneously monitor the contact angle variation and redistribution of the chemical species involved.ExperimentsMotivated by the enhanced oil recovery process of low salinity water flooding, we studied the response of picolitre oil drops on mineral substrates upon varying the ambient brine salinity. The substrates were pre-coated with thin layers of deuterated-stearic acid (surfactant) that display salinity-dependent stability.Findings3D CRM imaging using a recently proposed faster ‘ai’ (algorithm-improved) mode reveals that the surfactant layer is stable at high salinities, leading to preferential oil wetting. Upon reducing the ambient brine salinity, this layer decomposes and the investigated surfaces of mica and – somewhat less pronounced – silica become more water wet. Eventually, the surfactant is found to partly dissolve in the oil and partly precipitate at the oil-water interface. We anticipate that ai-3D-CRM will prove useful to holistically study similar systems displaying reactive wetting.

AB - HypothesisThe wettability of complex fluids on surfaces usually depends on the adsorption of solutes to any of the constituting interfaces. Controlling such interfacial processes by varying the composition of a phase enables the design of smart responsive systems. Our goal is to demonstrate that 3D Confocal Raman Microscopy (CRM) can reveal the mechanistic details of such processes by allowing to simultaneously monitor the contact angle variation and redistribution of the chemical species involved.ExperimentsMotivated by the enhanced oil recovery process of low salinity water flooding, we studied the response of picolitre oil drops on mineral substrates upon varying the ambient brine salinity. The substrates were pre-coated with thin layers of deuterated-stearic acid (surfactant) that display salinity-dependent stability.Findings3D CRM imaging using a recently proposed faster ‘ai’ (algorithm-improved) mode reveals that the surfactant layer is stable at high salinities, leading to preferential oil wetting. Upon reducing the ambient brine salinity, this layer decomposes and the investigated surfaces of mica and – somewhat less pronounced – silica become more water wet. Eventually, the surfactant is found to partly dissolve in the oil and partly precipitate at the oil-water interface. We anticipate that ai-3D-CRM will prove useful to holistically study similar systems displaying reactive wetting.

KW - Reactive wetting

KW - Raman Imaging

KW - Enhanced oil recovery

KW - Confocal Raman microscopy

KW - Surfactant

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DO - 10.1016/j.jcis.2020.10.016

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EP - 560

JO - Journal of colloid and interface science

JF - Journal of colloid and interface science

SN - 0021-9797

ER -

In-situ observation of reactive wettability alteration using algorithm-improved confocal Raman microscopy

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Keywords

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