Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability

Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability

We present an original method for measuring the intrinsic dissolution rate of gypsum. We use a simple microfluidic setup, with a gypsum block inserted between two polycarbonate plates, which is dissolved by water. By changing the flow rate and the distance between the plates, we can scan a wide rang...

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Main Authors: Osselin Florian, Kondratiuk Pawel, Cybulski Olgierd, Garstecki Piotr, Szymczak Piotr
Format: Article
Language:English
Published: EDP Sciences 2019-01-01
Series:E3S Web of Conferences
Online Access:https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_04010.pdf
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spelling doaj-041a771be1a54a76848380ef32f8620b2021-03-02T10:12:57ZengEDP SciencesE3S Web of Conferences2267-12422019-01-01980401010.1051/e3sconf/20199804010e3sconf_wri-162018_04010Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instabilityOsselin Florian0Kondratiuk Pawel1Cybulski Olgierd2Garstecki Piotr3Szymczak Piotr4Institut des Sciences de la Terre d'Orleans, 1A rue de la FérollerieInstitute of Theoretical Physics, Faculty of Physics, University of WarsawInstitute of Physical Chemistry, Polish Academy of SciencesInstitute of Physical Chemistry, Polish Academy of SciencesInstitute of Theoretical Physics, Faculty of Physics, University of WarsawWe present an original method for measuring the intrinsic dissolution rate of gypsum. We use a simple microfluidic setup, with a gypsum block inserted between two polycarbonate plates, which is dissolved by water. By changing the flow rate and the distance between the plates, we can scan a wide range of Péclet and Damköhler numbers, characterizing the relative magnitude of advection, diffusion and reaction in the system. We find the dissolution to be unstable, with a formation of a characteristic fingering pattern. The dissolution rate can then be calculated from the initial wavelength of this pattern. Alternatively, it can also be estimated from the time it takes for the gypsum chip to get completely dissolved near the inlet channel. The method presented here is general and can be used to assess the dissolution rates of other minerals.https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_04010.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Osselin Florian
Kondratiuk Pawel
Cybulski Olgierd
Garstecki Piotr
Szymczak Piotr
spellingShingle Osselin Florian
Kondratiuk Pawel
Cybulski Olgierd
Garstecki Piotr
Szymczak Piotr
Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
E3S Web of Conferences
author_facet Osselin Florian
Kondratiuk Pawel
Cybulski Olgierd
Garstecki Piotr
Szymczak Piotr
author_sort Osselin Florian
title Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
title_short Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
title_full Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
title_fullStr Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
title_full_unstemmed Microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
title_sort microfluidic measurement of the dissolution rate of gypsum in water using the reactive infiltration-instability
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2019-01-01
description We present an original method for measuring the intrinsic dissolution rate of gypsum. We use a simple microfluidic setup, with a gypsum block inserted between two polycarbonate plates, which is dissolved by water. By changing the flow rate and the distance between the plates, we can scan a wide range of Péclet and Damköhler numbers, characterizing the relative magnitude of advection, diffusion and reaction in the system. We find the dissolution to be unstable, with a formation of a characteristic fingering pattern. The dissolution rate can then be calculated from the initial wavelength of this pattern. Alternatively, it can also be estimated from the time it takes for the gypsum chip to get completely dissolved near the inlet channel. The method presented here is general and can be used to assess the dissolution rates of other minerals.
url https://www.e3s-conferences.org/articles/e3sconf/pdf/2019/24/e3sconf_wri-162018_04010.pdf
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AT cybulskiolgierd microfluidicmeasurementofthedissolutionrateofgypsuminwaterusingthereactiveinfiltrationinstability
AT garsteckipiotr microfluidicmeasurementofthedissolutionrateofgypsuminwaterusingthereactiveinfiltrationinstability
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