Abstract
We investigate meniscus shapes and capillary rise heights in glass capillaries with rectangular cross sections (4 × 0.2 mm), which we modified with established coatings to generate a range of surfaces that interact differently with water. Meniscus positions and shapes are imaged while the capillaries are rotated horizontally about their longitudinal axis in order to generate centrifugal forces opposing the capillary driven fluid propagation, i.e. volumetric forces. Changing the rotational speed allows us to balance both forces thereby bringing capillary rise to a stop. In brief, we find very good agreement of the different meniscus shapes we observe over a wide range of centrifugal accelerations (up to 191 g) with two independent simulations of the scenario. In addition, we are able to precisely measure capillary rise heights in differently modified capillaries over a range of centrifugal accelerations and correlate these values. Lastly, we mention how this system will prove useful to investigate wetting phenomena on swellable surfaces, i.e. surfaces whose properties dynamically change upon fluid contact, by providing precise control over the propagation speed of the three phase contact line.
Item Type: |
Article
|
Erschienen: |
2021 |
Creators: |
Fickel, Beatrice ; Postulka, Niels ; Hartmann, Maximilian ; Gründing, Dirk M. ; Nau, Maximilian ; Meckel, Tobias ; Biesalski, Markus |
Type of entry: |
Bibliographie |
Title: |
Changes of meniscus shapes and capillary rise heights under hypergravity |
Language: |
English |
Date: |
5 February 2021 |
Publisher: |
Elsevier ScienceDirect |
Journal or Publication Title: |
Colloids and Surfaces A: Physicochemical and Engineering Aspects |
Volume of the journal: |
610 |
Collation: |
7 Seiten |
DOI: |
10.1016/j.colsurfa.2020.125688 |
Abstract: |
We investigate meniscus shapes and capillary rise heights in glass capillaries with rectangular cross sections (4 × 0.2 mm), which we modified with established coatings to generate a range of surfaces that interact differently with water. Meniscus positions and shapes are imaged while the capillaries are rotated horizontally about their longitudinal axis in order to generate centrifugal forces opposing the capillary driven fluid propagation, i.e. volumetric forces. Changing the rotational speed allows us to balance both forces thereby bringing capillary rise to a stop. In brief, we find very good agreement of the different meniscus shapes we observe over a wide range of centrifugal accelerations (up to 191 g) with two independent simulations of the scenario. In addition, we are able to precisely measure capillary rise heights in differently modified capillaries over a range of centrifugal accelerations and correlate these values. Lastly, we mention how this system will prove useful to investigate wetting phenomena on swellable surfaces, i.e. surfaces whose properties dynamically change upon fluid contact, by providing precise control over the propagation speed of the three phase contact line. |
Additional Information: |
Art.No.: 125688 |
Divisions: |
10 Department of Biology 10 Department of Biology > Membrane Dynamics 16 Department of Mechanical Engineering DFG-Collaborative Research Centres (incl. Transregio) DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes > Research Area A: Generic Experiments DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes > Research Area A: Generic Experiments > A02: Experimental Investigation of Coalescence and Breakup of Droplets on Solid Surfaces – Generic Configuration Sessile Drop DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes > Research Area A: Generic Experiments > A05: Wetting and Transport on Swellable, Immobilized Polymer Brushes and Polymer Networks DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes > Research Area B: Modeling and Simulation DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1194: Interaction between Transport and Wetting Processes > Research Area B: Modeling and Simulation > B02: Direct Numerical Simulation of Locally Coupled Interface Processes at Dynamic Contact Lines Profile Areas Profile Areas > Thermo-Fluids & Interfaces 04 Department of Mathematics 04 Department of Mathematics > Analysis 04 Department of Mathematics > Analysis > Mathematical Modeling and Analysis 07 Department of Chemistry 07 Department of Chemistry > Ernst-Berl-Institut 07 Department of Chemistry > Ernst-Berl-Institut > Fachgebiet Makromolekulare Chemie 04 Department of Mathematics > Mathematical Modelling and Analysis 16 Department of Mechanical Engineering > Institute for Nano- and Microfluidics (NMF) |
TU-Projects: |
DFG|SFB1194|TP A02 Hardt DFG|SFB1194|TP A05 Biesalski DFG|SFB1194|TP B02 Marshall |
Date Deposited: |
02 Feb 2021 08:42 |
Last Modified: |
07 Feb 2024 11:55 |
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