Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique

Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique

The wetting of rough polymer surfaces is of great importance for many technical applications. In this paper, we demonstrate the relationship between the mean roughness values and the fractal dimension of rough and self-affine PTFE surfaces. We have used white light interferometry measurements to obt...

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Main Authors: Christian W. Karl, Andrey E. Krauklis, Andrej Lang, Ulrich Giese
Format: Article
Language:English
Published: MDPI AG 2020-07-01
Series:Polymers
Subjects:
polytetrafluoroethylene
PTFE
roughness
fractal dimension
mean roughness
contact angle
Online Access:https://www.mdpi.com/2073-4360/12/7/1528
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spelling doaj-e9958c9800f44f80af3a6927488b06e42020-11-25T03:43:28ZengMDPI AGPolymers2073-43602020-07-01121528152810.3390/polym12071528Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance TechniqueChristian W. Karl0Andrey E. Krauklis1Andrej Lang2Ulrich Giese3Materials and Nanotechnology Dept., SINTEF Industry, Forskningsveien 1, 0373 Oslo, NorwayMaterials and Nanotechnology Dept., SINTEF Industry, Forskningsveien 1, 0373 Oslo, NorwayGerman Institute of Rubber Technology (DIK e. V.), Eupener Str. 33, 30519 Hanover, GermanyGerman Institute of Rubber Technology (DIK e. V.), Eupener Str. 33, 30519 Hanover, GermanyThe wetting of rough polymer surfaces is of great importance for many technical applications. In this paper, we demonstrate the relationship between the mean roughness values and the fractal dimension of rough and self-affine PTFE surfaces. We have used white light interferometry measurements to obtain information about the complex topography of the technical surfaces having different height distributions. Two different methods for the calculation of the fractal dimension were used: The height difference correlation function (HDC) and the cube counting method. It was demonstrated that the mean roughness value (<i>R<sub>a</sub></i>) correlates better with the fractal dimension <i>D<sub>f</sub></i> determined by the cube counting method than with the <i>D<sub>f</sub></i> values obtained from HDC calculations. However, the HDC values show a stronger dependency by changing the surface roughness. The advancing and receding contact angles as well as the contact angle hysteresis of PTFE samples of different roughness were studied by the modified Wilhelmy balance technique using deionized water as a liquid. The modified Wilhelmy balance technique enables the possibility for future analysis of very rough PTFE surfaces which are difficult to investigate with the sessile drop method.https://www.mdpi.com/2073-4360/12/7/1528polytetrafluoroethylenePTFEroughnessfractal dimensionmean roughnesscontact angle
collection DOAJ
language English
format Article
sources DOAJ
author Christian W. Karl
Andrey E. Krauklis
Andrej Lang
Ulrich Giese
spellingShingle Christian W. Karl
Andrey E. Krauklis
Andrej Lang
Ulrich Giese
Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
Polymers
polytetrafluoroethylene
PTFE
roughness
fractal dimension
mean roughness
contact angle
author_facet Christian W. Karl
Andrey E. Krauklis
Andrej Lang
Ulrich Giese
author_sort Christian W. Karl
title Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
title_short Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
title_full Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
title_fullStr Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
title_full_unstemmed Characterization of Rough PTFE Surfaces by the Modified Wilhelmy Balance Technique
title_sort characterization of rough ptfe surfaces by the modified wilhelmy balance technique
publisher MDPI AG
series Polymers
issn 2073-4360
publishDate 2020-07-01
description The wetting of rough polymer surfaces is of great importance for many technical applications. In this paper, we demonstrate the relationship between the mean roughness values and the fractal dimension of rough and self-affine PTFE surfaces. We have used white light interferometry measurements to obtain information about the complex topography of the technical surfaces having different height distributions. Two different methods for the calculation of the fractal dimension were used: The height difference correlation function (HDC) and the cube counting method. It was demonstrated that the mean roughness value (<i>R<sub>a</sub></i>) correlates better with the fractal dimension <i>D<sub>f</sub></i> determined by the cube counting method than with the <i>D<sub>f</sub></i> values obtained from HDC calculations. However, the HDC values show a stronger dependency by changing the surface roughness. The advancing and receding contact angles as well as the contact angle hysteresis of PTFE samples of different roughness were studied by the modified Wilhelmy balance technique using deionized water as a liquid. The modified Wilhelmy balance technique enables the possibility for future analysis of very rough PTFE surfaces which are difficult to investigate with the sessile drop method.
topic polytetrafluoroethylene
PTFE
roughness
fractal dimension
mean roughness
contact angle
url https://www.mdpi.com/2073-4360/12/7/1528
work_keys_str_mv AT christianwkarl characterizationofroughptfesurfacesbythemodifiedwilhelmybalancetechnique
AT andreyekrauklis characterizationofroughptfesurfacesbythemodifiedwilhelmybalancetechnique
AT andrejlang characterizationofroughptfesurfacesbythemodifiedwilhelmybalancetechnique
AT ulrichgiese characterizationofroughptfesurfacesbythemodifiedwilhelmybalancetechnique
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