Rapid Characterization of Multiple-Contact Miscibility: Toward a Slim-Tube on a Chip

Zou, Hanbang; Slim, Anja C.; Neild, Adrian

doi:10.1021/acs.analchem.9b02893

Cited by 7 publications

(3 citation statements)

References 41 publications

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Section: Resultsmentioning

confidence: 99%

“…In this way, the captured droplets are exposed to fresh buffer, hence no unwanted merging events can occur between suspended and captured droplets, and the diffusive process is one of first contact. 29 Finally, after the self-assembly process has continued for the desired time, it is necessary to remove the droplets, (ESI † Video S7). The required flow conditions are depicted in Fig.…”

Section: (A)) (Esi † Video S2)mentioning

confidence: 99%

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Nonequilibrium interfacial diffusion across microdroplet interface

Khoeini

Boyd

et al. 2022

Lab Chip

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Section: Resultsmentioning

confidence: 99%

Section: (A)) (Esi † Video S2)mentioning

confidence: 99%

Nonequilibrium interfacial diffusion across microdroplet interface

Khoeini

Boyd

et al. 2022

Lab Chip

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“…Zou et al [60] presented a microchannel design similar to a single-pore-width slim tube with several inline pocket structures. The ternary fluid system was used as an analogue of the crude oil-gas system, where water stood in for gas, ethanol for light hydrocarbons and hexanol for heavy hydrocarbons.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic Studies on Minimum Miscibility Pressure for n-Decane and CO2

et al. 2023

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Oil production is a complex process that can be made more efficient by applying gas enhanced oil recovery (EOR) methods. Thus, it is essential to know the minimum miscibility pressure (MMP) and minimum miscibility enrichment (MME) of gas in oil. Conventional slim-tube experiments for the measurement of MMP require hundreds of millilitres of real or recombined oil and last over 30 days. Advances in microfluidic technology allow the reduction of the amount of fluid and the time required in determining MMP (or MME), hence making the process rapid. In this study, we developed a microfluidic model with a stochastically distributed pore network, porosity of 74.6% and volume of 83.26 nanolitres. Although the volume was six orders of magnitude smaller than the slim tube, it retained the same proportions, guaranteeing a proper comparison between the tests. This microfluidic chip allowed the study of the MMP of n-decane with carbon dioxide at two different temperature conditions. The experimental results coincided with the results received both from conventional and microfluidic experiments. Furthermore, a numerical simulation of a section of the microfluidic model under the experimental conditions presented results within acceptable margins of the experimental ones. The results of the presented methodology indicate the potential to replace conventional technology for the measurement of MMP with microfluidic technology. Its promise lies in accelerating laboratory tests and increasing the reliability of experimental results and, subsequently, the quality of field gas EOR operations.

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Rapid Characterization of Multiple-Contact Miscibility: Toward a Slim-Tube on a Chip

Cited by 7 publications

References 41 publications

Nonequilibrium interfacial diffusion across microdroplet interface

Nonequilibrium interfacial diffusion across microdroplet interface

Microfluidic Studies on Minimum Miscibility Pressure for n-Decane and CO2

Advances in sour gas injection for enhanced oil recovery-an economical and environmental way for handling excessively produced H2S

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