Conformational changes influence clogging behavior of micrometer-sized microgels in idealized multiple constrictions

Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane f...

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Published in	Scientific reports Vol. 9; no. 1; pp. 9241 - 9
Main Authors	Bouhid de Aguiar, Izabella, Meireles, Martine, Bouchoux, Antoine, Schroën, Karin
Format	Journal Article
Language	English
Published	London Nature Publishing Group UK 25.06.2019 Nature Publishing Group
Subjects	639/166/898 639/301/923 Cameras Channel pores Chemical and Process Engineering Chemical engineering Chemical Sciences Engineering Sciences Food Process Engineering Humanities and Social Sciences Leerstoelgroep Levensmiddelenproceskunde Levensmiddelenproceskunde Membrane filtration Microfluidics multidisciplinary Particle size Porous media Science Science (multidisciplinary) VLAG Clogging microgels Microfluidic
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Abstract	Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane filtration and perform in situ observations of the pore clogging mechanisms with the aid of high speed cameras. In this work, we use microfluidic devices composed by an array of parallel channels to observe the clogging behavior of micrometer sized microgels. It is important to note that the microgels are larger than the pores/constrictions. We quantify the clog propensity in relation to the clogging position and particle size and find that the majority of the microgels clog at the first constriction independently of particle size and constriction entrance angle. We also quantify the variations in shape and volume (2D projection) of the microgels in relation to particle size and constriction entrance angle. We find that the degree of deformation increases with particle size and is dependent of constriction entrance angle, whereas, changes in volume do not depend on entrance angle.
AbstractList	Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane filtration and perform in situ observations of the pore clogging mechanisms with the aid of high speed cameras. In this work, we use microfluidic devices composed by an array of parallel channels to observe the clogging behavior of micrometer sized microgels. It is important to note that the microgels are larger than the pores/constrictions. We quantify the clog propensity in relation to the clogging position and particle size and find that the majority of the microgels clog at the first constriction independently of particle size and constriction entrance angle. We also quantify the variations in shape and volume (2D projection) of the microgels in relation to particle size and constriction entrance angle. We find that the degree of deformation increases with particle size and is dependent of constriction entrance angle, whereas, changes in volume do not depend on entrance angle. Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane filtration and perform in situ observations of the pore clogging mechanisms with the aid of high speed cameras. In this work, we use microfluidic devices composed by an array of parallel channels to observe the clogging behavior of micrometer sized microgels. It is important to note that the microgels are larger than the pores/constrictions. We quantify the clog propensity in relation to the clogging position and particle size and find that the majority of the microgels clog at the first constriction independently of particle size and constriction entrance angle. We also quantify the variations in shape and volume (2D projection) of the microgels in relation to particle size and constriction entrance angle. We find that the degree of deformation increases with particle size and is dependent of constriction entrance angle, whereas, changes in volume do not depend on entrance angle. Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane filtration and perform in situ observations of the pore clogging mechanisms with the aid of high speed cameras. In this work, we use microfluidic devices composed by an array of parallel channels to observe the clogging behavior of micrometer sized microgels. It is important to note that the microgels are larger than the pores/constrictions. We quantify the clog propensity in relation to the clogging position and particle size and find that the majority of the microgels clog at the first constriction independently of particle size and constriction entrance angle. We also quantify the variations in shape and volume (2D projection) of the microgels in relation to particle size and constriction entrance angle. We find that the degree of deformation increases with particle size and is dependent of constriction entrance angle, whereas, changes in volume do not depend on entrance angle.Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of great importance for process optimization. The rise in the utilization of microfluidic devices brought the possibility to simulate membrane filtration and perform in situ observations of the pore clogging mechanisms with the aid of high speed cameras. In this work, we use microfluidic devices composed by an array of parallel channels to observe the clogging behavior of micrometer sized microgels. It is important to note that the microgels are larger than the pores/constrictions. We quantify the clog propensity in relation to the clogging position and particle size and find that the majority of the microgels clog at the first constriction independently of particle size and constriction entrance angle. We also quantify the variations in shape and volume (2D projection) of the microgels in relation to particle size and constriction entrance angle. We find that the degree of deformation increases with particle size and is dependent of constriction entrance angle, whereas, changes in volume do not depend on entrance angle.
ArticleNumber	9241
Author	Schroën, Karin Bouchoux, Antoine Bouhid de Aguiar, Izabella Meireles, Martine
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Cites_doi	10.1016/j.actbio.2018.07.003 10.1016/j.memsci.2015.01.033 10.1038/s41598-016-0028-x 10.1007/s10544-018-0297-1 10.1103/PhysRevE.96.062605 10.1016/j.memsci.2017.04.014 10.1016/j.seppur.2014.01.041 10.1039/C6SM01879C 10.1016/j.ifset.2012.12.007 10.1016/j.seppur.2018.01.057 10.1007/s41745-018-0071-7 10.1016/j.memsci.2015.06.007 10.1038/s41598-019-39820-z 10.1038/s41598-018-30389-7 10.1038/s41598-017-10788-y 10.1016/j.memsci.2012.04.002 10.1039/c3sm51594j 10.1016/j.cej.2017.12.078 10.1039/c2fd20022h 10.1039/C6SM02674E 10.1038/s41598-018-24088-6 10.1039/C6SM01345G 10.1080/01496395.2016.1187629 10.1016/j.watres.2010.12.018 10.1038/srep28450 10.1002/ceat.201000099
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Snippet	Clogging of porous media by soft particles has become a subject of extensive research in the last years and the understanding of the clogging mechanisms is of...
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SubjectTerms	639/166/898 639/301/923 Cameras Channel pores Chemical and Process Engineering Chemical engineering Chemical Sciences Engineering Sciences Food Process Engineering Humanities and Social Sciences Leerstoelgroep Levensmiddelenproceskunde Levensmiddelenproceskunde Membrane filtration Microfluidics multidisciplinary Particle size Porous media Science Science (multidisciplinary) VLAG
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Title	Conformational changes influence clogging behavior of micrometer-sized microgels in idealized multiple constrictions
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