Fabrication of PVDF-blended ultrafiltration membranes incorporated by chiral mesoporous silica for enantioseparation

[Display omitted] •The asymmetric helical channel structures caused the chiral features of mesoporous SiO2.•PVDF blended membranes incorporated with chiral mesoporous SiO2 were constructed.•The hydrophilicity and polarity of the PVDF was improved by chiral mesoporous SiO2.•All membranes containing c...

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Published inJournal of industrial and engineering chemistry (Seoul, Korea) Vol. 109; pp. 568 - 577
Main Authors Wang, Ting, Huang, Xiao-xing, Wu, Li-guang, Li, Chun-juan, Zhu, Dong-feng
Format Journal Article
LanguageEnglish
Published Elsevier B.V 25.05.2022
한국공업화학회
Subjects
Chiral mesoporous SiO2
Enantioseparation
Mixed-matrix membranes
PVDF
Ultrafiltration
화학공학
Mixed-matrix membranes
Ultrafiltration
Enantioseparation
PVDF
Chiral mesoporous SiO2
Online AccessGet full text
ISSN1226-086X
1876-794X
DOI10.1016/j.jiec.2022.02.046

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Abstract [Display omitted] •The asymmetric helical channel structures caused the chiral features of mesoporous SiO2.•PVDF blended membranes incorporated with chiral mesoporous SiO2 were constructed.•The hydrophilicity and polarity of the PVDF was improved by chiral mesoporous SiO2.•All membranes containing chiral mesoporous SiO2 had enantioseparation performance.•The addition of β-CD would further improve the enantioselectivity of the membranes. Novel poly(vinylidene fluoride) (PVDF) ultrafiltration membranes blending with chiral mesoporous SiO2 materials were constructed to improve the anti-fouling and separation performance of PVDF-blended membranes. The formation of asymmetric mesoporous structure of chiral mesoporous SiO2 caused their large hydrophilic surface and significant chiral features, which enhanced the hydrophilicity and polarity of the resulting PVDF membranes blended with chiral mesoporous SiO2. So, the PVDF-blended membranes containing chiral mesoporous SiO2 had a high permeation performance and anti-fouling property. After blending with chiral mesoporous SiO2, the maximum flux of membranes exceeded 500 L·m−2·h−1 and was 6.5-fold higher than that of neat PVDF. Due to the stereo-specific interaction between enantiomers and chiral recognition sites introduced by chiral mesoporous SiO2 in the membranes, all PVDF-blended membranes had evident enantioseparation performance for DL-racemic tryptophan. The C-SiO2-20/PVDF-blended membranes had the highest enantioseparation performance under the same addition content and the maximum enantiomeric excess (e.e.%) was more than 20 %. Given the strong stereo-specific interaction and hydrogen bonding between d-tryptophan and β-cyclodextrin (β-CD), the addition of more β-CD would introduce more chiral recognition sites into the membranes, thereby enhancing the enantioseparation performance of the membranes for d-tryptophan. The maximum e.e.% of C-SiO2-20/β-CD/PVDF-blended membranes for the tryptophan enantiomer reached 55%.
AbstractList Novel poly(vinylidene fluoride) (PVDF) ultrafiltration membranes blending with chiral mesoporous SiO2materials were constructed to improve the anti-fouling and separation performance of PVDF-blendedmembranes. The formation of asymmetric mesoporous structure of chiral mesoporous SiO2 caused theirlarge hydrophilic surface and significant chiral features, which enhanced the hydrophilicity and polarityof the resulting PVDF membranes blended with chiral mesoporous SiO2. So, the PVDF-blended membranescontaining chiral mesoporous SiO2 had a high permeation performance and anti-fouling property. After blending with chiral mesoporous SiO2, the maximum flux of membranes exceeded 500 Lm2h1and was 6.5-fold higher than that of neat PVDF. Due to the stereo-specific interaction between enantiomersand chiral recognition sites introduced by chiral mesoporous SiO2 in the membranes, allPVDF-blended membranes had evident enantioseparation performance for DL-racemic tryptophan. TheC-SiO2-20/PVDF-blended membranes had the highest enantioseparation performance under the sameaddition content and the maximum enantiomeric excess (e.e.%) was more than 20 %. Given the strongstereo-specific interaction and hydrogen bonding between d-tryptophan and b-cyclodextrin (b-CD), theaddition of more b-CD would introduce more chiral recognition sites into the membranes, therebyenhancing the enantioseparation performance of the membranes for d-tryptophan. The maximum e.e. % of C-SiO2-20/b-CD/PVDF-blended membranes for the tryptophan enantiomer reached 55%. KCI Citation Count: 0
[Display omitted] •The asymmetric helical channel structures caused the chiral features of mesoporous SiO2.•PVDF blended membranes incorporated with chiral mesoporous SiO2 were constructed.•The hydrophilicity and polarity of the PVDF was improved by chiral mesoporous SiO2.•All membranes containing chiral mesoporous SiO2 had enantioseparation performance.•The addition of β-CD would further improve the enantioselectivity of the membranes. Novel poly(vinylidene fluoride) (PVDF) ultrafiltration membranes blending with chiral mesoporous SiO2 materials were constructed to improve the anti-fouling and separation performance of PVDF-blended membranes. The formation of asymmetric mesoporous structure of chiral mesoporous SiO2 caused their large hydrophilic surface and significant chiral features, which enhanced the hydrophilicity and polarity of the resulting PVDF membranes blended with chiral mesoporous SiO2. So, the PVDF-blended membranes containing chiral mesoporous SiO2 had a high permeation performance and anti-fouling property. After blending with chiral mesoporous SiO2, the maximum flux of membranes exceeded 500 L·m−2·h−1 and was 6.5-fold higher than that of neat PVDF. Due to the stereo-specific interaction between enantiomers and chiral recognition sites introduced by chiral mesoporous SiO2 in the membranes, all PVDF-blended membranes had evident enantioseparation performance for DL-racemic tryptophan. The C-SiO2-20/PVDF-blended membranes had the highest enantioseparation performance under the same addition content and the maximum enantiomeric excess (e.e.%) was more than 20 %. Given the strong stereo-specific interaction and hydrogen bonding between d-tryptophan and β-cyclodextrin (β-CD), the addition of more β-CD would introduce more chiral recognition sites into the membranes, thereby enhancing the enantioseparation performance of the membranes for d-tryptophan. The maximum e.e.% of C-SiO2-20/β-CD/PVDF-blended membranes for the tryptophan enantiomer reached 55%.
Author Wu, Li-guang
Wang, Ting
Huang, Xiao-xing
Li, Chun-juan
Zhu, Dong-feng
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Keywords Mixed-matrix membranes
Ultrafiltration
Enantioseparation
PVDF
Chiral mesoporous SiO2
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한국공업화학회
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Snippet [Display omitted] •The asymmetric helical channel structures caused the chiral features of mesoporous SiO2.•PVDF blended membranes incorporated with chiral...
Novel poly(vinylidene fluoride) (PVDF) ultrafiltration membranes blending with chiral mesoporous SiO2materials were constructed to improve the anti-fouling and...
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SubjectTerms Chiral mesoporous SiO2
Enantioseparation
Mixed-matrix membranes
PVDF
Ultrafiltration
화학공학
Title Fabrication of PVDF-blended ultrafiltration membranes incorporated by chiral mesoporous silica for enantioseparation
URI https://dx.doi.org/10.1016/j.jiec.2022.02.046
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