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Fluid Flow Programming in Paper-Derived Silica–Polymer Hybrids

Dubois, Christelle ; Herzog, Nicole ; Rüttiger, Christian ; Geißler, Andreas ; Grange, Eléonor ; Kunz, Ulrike ; Kleebe, Hans-Joachim ; Biesalski, Markus ; Meckel, Tobias ; Gutmann, Torsten ; Gallei, Markus ; Andrieu-Brunsen, Annette (2022)
Fluid Flow Programming in Paper-Derived Silica–Polymer Hybrids.
In: Langmuir, 2017, 33 (1)
doi: 10.26083/tuprints-00021675
Article, Secondary publication, Postprint

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Item Type: Article
Type of entry: Secondary publication
Title: Fluid Flow Programming in Paper-Derived Silica–Polymer Hybrids
Language: English
Date: 2022
Place of Publication: Darmstadt
Year of primary publication: 2017
Publisher: ACS Publications
Journal or Publication Title: Langmuir
Volume of the journal: 33
Issue Number: 1
Collation: 22 Seiten
DOI: 10.26083/tuprints-00021675
Corresponding Links:
Origin: Secondary publication service
Abstract:

In paper-based devices, capillary fluid flow is based on length-scale selective functional control within a hierarchical porous system. The fluid flow can be tuned by altering the paper preparation process, which controls parameters such as the paper grammage. Interestingly, the fiber morphology and nanoporosity are often neglected. In this work, porous voids are incorporated into paper by the combination of dense or mesoporous ceramic silica coatings with hierarchically porous cotton linter paper. Varying the silica coating leads to significant changes in the fluid flow characteristics, up to the complete water exclusion without any further fiber surface hydrophobization, providing new approaches to control fluid flow. Additionally, functionalization with redox-responsive polymers leads to reversible, dynamic gating of fluid flow in these hybrid paper materials, demonstrating the potential of length scale specific, dynamic, and external transport control.

Uncontrolled Keywords: mesoporous silica hybrid paper, sol-gel chemistry, redox-gating, capillary fluid flow, paper-based microfluidic devices
Status: Postprint
URN: urn:nbn:de:tuda-tuprints-216753
Classification DDC: 500 Science and mathematics > 540 Chemistry
Divisions: 10 Department of Biology > Membrane Dynamics
11 Department of Materials and Earth Sciences > Material Science > Physical Metallurgy
07 Department of Chemistry > Ernst-Berl-Institut > Fachgebiet Makromolekulare Chemie
Date Deposited: 20 Jul 2022 12:07
Last Modified: 11 Jan 2023 14:18
URI: https://tuprints.ulb.tu-darmstadt.de/id/eprint/21675
PPN: 503519685
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