Predicting plastron thermodynamic stability for underwater superhydrophobicity

Alexander B. Tesler; Heikki A. Nurmi; Stefan Kolle; Lucia H. Prado; Bhuvaneshwari Karunakaran; Anca Mazare; Ina Erceg; Íris de Brito Soares; George Sarau; Silke Christiansen; Shane Stafslien; Jack Alvarenga; Joanna Aizenberg; Ben Fabry; Robin H.A. Ras; Wolfgang H. Goldmann

doi:10.1038/s43246-024-00555-8

Predicting plastron thermodynamic stability for underwater superhydrophobicity

Alexander B. Tesler^*
, Heikki A. Nurmi
, Stefan Kolle
, Lucia H. Prado
, Bhuvaneshwari Karunakaran
, Anca Mazare
, Ina Erceg
, Íris de Brito Soares
, George Sarau
, Silke Christiansen
, Shane Stafslien
, Jack Alvarenga
, Joanna Aizenberg
, Ben Fabry
, Robin H.A. Ras^*
, Wolfgang H. Goldmann^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

18 Citations (Scopus)

34 Downloads (Pure)

Abstract

Non-wettable surfaces, especially those capable of passively trapping air in rough protrusions, can provide surface resilience to the detrimental effects of wetting-related phenomena. However, the development of such superhydrophobic surfaces with a long-lasting entrapped air layer, called plastron, is hampered by the lack of evaluation criteria and methods that can unambiguously distinguish between stable and metastable Cassie-Baxter wetting regimes. The information to evaluate the stability of the wetting regime is missing from the commonly used contact angle goniometry. Therefore, it is necessary to determine which surface features can be used as a signature to identify thermodynamically stable plastron. Here, we describe a methodology for evaluating the thermodynamic underwater stability of the Cassie-Baxter wetting regime of superhydrophobic surfaces by measuring the surface roughness, solid-liquid area fraction, and Young’s contact angle. The method allowed the prediction of passive plastron stability for over one year of continuous submersion, the impeding of mussel and barnacle adhesion, and inhibition of metal corrosion in seawater. Such submersion-stable superhydrophobicity, in which water is repelled by a stable passive air layer trapped between the solid substrate and the surrounding liquid for extended periods at ambient conditions, opens new avenues for science and technologies that require continuous contact of solids with aqueous media. (Figure presented.).

Original language	English
Article number	112
Pages (from-to)	1-10
Number of pages	10
Journal	Communications Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s43246-024-00555-8
Publication status	Published - 29 Jun 2024
MoE publication type	A1 Journal article-refereed

Funding

A.B.T. thanks the Deutsche Forschungsgemeinschaft (DFG) (award number 540989797) for financial support. A.B.T., W.H.G., and B.F. thank the Deutsche Forschungsgemeinschaft (DFG) (award number 442826449) for financial support. H.A.N., B.K., and R.H.A.R. acknowledge funding from the Academy of Finland Center of Excellence Program (2022 − 2029) in Life-Inspired Hybrid Materials (LIBER, project number 346109). S.S. acknowledges funding from the Office of Naval Research, U.S. Department of Defense Grant N00014-17-1-2153. S.K. and J.A. acknowledge funding from the Office of Naval Research, U.S. Department of Defense grants: N00014-15-1-2323, N00014-17-1-2913, and the Department of Energy (Award DE-SC0005247). I.d.B.S. and S.C. were supported by the European Union’s H2020 research and innovation program under the Marie Sklodowska-Curie grant agreement AIMed ID: 861138. G.S., I.E., and S.C. acknowledge the financial support from the European Union within the research projects 4D + nanoSCOPE ID: 810316, LRI ID: C10, STOP ID: 101057961, from the German Research Foundation (DFG) within the research project UNPLOK ID: 523847126, and from the “Freistaat Bayern” and European Union within the project Analytiktechnikum für Gesundheits- und Umweltforschung AGEUM, StMWi-43-6623-22/1/3. The authors thank Prof. S. Virtanen and Prof. P. Schmuki for providing laboratory space for measurements. W.H.G. and A.B.T. are indebted to Liz Nicholson (MA) for proofreading the manuscript.

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Predicting plastron thermodynamic stability for underwater superhydrophobicityFinal published version, 3.32 MBLicence: CC BY

Cite this

Tesler, A. B., Nurmi, H. A., Kolle, S., Prado, L. H., Karunakaran, B., Mazare, A., Erceg, I., de Brito Soares, Í., Sarau, G., Christiansen, S., Stafslien, S., Alvarenga, J., Aizenberg, J., Fabry, B., Ras, R. H. A., & Goldmann, W. H. (2024). Predicting plastron thermodynamic stability for underwater superhydrophobicity. Communications Materials, 5(1), 1-10. Article 112. https://doi.org/10.1038/s43246-024-00555-8

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title = "Predicting plastron thermodynamic stability for underwater superhydrophobicity",

abstract = "Non-wettable surfaces, especially those capable of passively trapping air in rough protrusions, can provide surface resilience to the detrimental effects of wetting-related phenomena. However, the development of such superhydrophobic surfaces with a long-lasting entrapped air layer, called plastron, is hampered by the lack of evaluation criteria and methods that can unambiguously distinguish between stable and metastable Cassie-Baxter wetting regimes. The information to evaluate the stability of the wetting regime is missing from the commonly used contact angle goniometry. Therefore, it is necessary to determine which surface features can be used as a signature to identify thermodynamically stable plastron. Here, we describe a methodology for evaluating the thermodynamic underwater stability of the Cassie-Baxter wetting regime of superhydrophobic surfaces by measuring the surface roughness, solid-liquid area fraction, and Young{\textquoteright}s contact angle. The method allowed the prediction of passive plastron stability for over one year of continuous submersion, the impeding of mussel and barnacle adhesion, and inhibition of metal corrosion in seawater. Such submersion-stable superhydrophobicity, in which water is repelled by a stable passive air layer trapped between the solid substrate and the surrounding liquid for extended periods at ambient conditions, opens new avenues for science and technologies that require continuous contact of solids with aqueous media. (Figure presented.).",

author = "Tesler, \{Alexander B.\} and Nurmi, \{Heikki A.\} and Stefan Kolle and Prado, \{Lucia H.\} and Bhuvaneshwari Karunakaran and Anca Mazare and Ina Erceg and \{de Brito Soares\}, {\'I}ris and George Sarau and Silke Christiansen and Shane Stafslien and Jack Alvarenga and Joanna Aizenberg and Ben Fabry and Ras, \{Robin H.A.\} and Goldmann, \{Wolfgang H.\}",

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Tesler, AB, Nurmi, HA, Kolle, S, Prado, LH, Karunakaran, B, Mazare, A, Erceg, I, de Brito Soares, Í, Sarau, G, Christiansen, S, Stafslien, S, Alvarenga, J, Aizenberg, J, Fabry, B, Ras, RHA & Goldmann, WH 2024, 'Predicting plastron thermodynamic stability for underwater superhydrophobicity', Communications Materials, vol. 5, no. 1, 112, pp. 1-10. https://doi.org/10.1038/s43246-024-00555-8

TY - JOUR

T1 - Predicting plastron thermodynamic stability for underwater superhydrophobicity

AU - Tesler, Alexander B.

AU - Nurmi, Heikki A.

AU - Kolle, Stefan

AU - Prado, Lucia H.

AU - Karunakaran, Bhuvaneshwari

AU - Mazare, Anca

AU - Erceg, Ina

AU - de Brito Soares, Íris

AU - Sarau, George

AU - Christiansen, Silke

AU - Stafslien, Shane

AU - Alvarenga, Jack

AU - Aizenberg, Joanna

AU - Fabry, Ben

AU - Ras, Robin H.A.

AU - Goldmann, Wolfgang H.

PY - 2024/6/29

Y1 - 2024/6/29

N2 - Non-wettable surfaces, especially those capable of passively trapping air in rough protrusions, can provide surface resilience to the detrimental effects of wetting-related phenomena. However, the development of such superhydrophobic surfaces with a long-lasting entrapped air layer, called plastron, is hampered by the lack of evaluation criteria and methods that can unambiguously distinguish between stable and metastable Cassie-Baxter wetting regimes. The information to evaluate the stability of the wetting regime is missing from the commonly used contact angle goniometry. Therefore, it is necessary to determine which surface features can be used as a signature to identify thermodynamically stable plastron. Here, we describe a methodology for evaluating the thermodynamic underwater stability of the Cassie-Baxter wetting regime of superhydrophobic surfaces by measuring the surface roughness, solid-liquid area fraction, and Young’s contact angle. The method allowed the prediction of passive plastron stability for over one year of continuous submersion, the impeding of mussel and barnacle adhesion, and inhibition of metal corrosion in seawater. Such submersion-stable superhydrophobicity, in which water is repelled by a stable passive air layer trapped between the solid substrate and the surrounding liquid for extended periods at ambient conditions, opens new avenues for science and technologies that require continuous contact of solids with aqueous media. (Figure presented.).

AB - Non-wettable surfaces, especially those capable of passively trapping air in rough protrusions, can provide surface resilience to the detrimental effects of wetting-related phenomena. However, the development of such superhydrophobic surfaces with a long-lasting entrapped air layer, called plastron, is hampered by the lack of evaluation criteria and methods that can unambiguously distinguish between stable and metastable Cassie-Baxter wetting regimes. The information to evaluate the stability of the wetting regime is missing from the commonly used contact angle goniometry. Therefore, it is necessary to determine which surface features can be used as a signature to identify thermodynamically stable plastron. Here, we describe a methodology for evaluating the thermodynamic underwater stability of the Cassie-Baxter wetting regime of superhydrophobic surfaces by measuring the surface roughness, solid-liquid area fraction, and Young’s contact angle. The method allowed the prediction of passive plastron stability for over one year of continuous submersion, the impeding of mussel and barnacle adhesion, and inhibition of metal corrosion in seawater. Such submersion-stable superhydrophobicity, in which water is repelled by a stable passive air layer trapped between the solid substrate and the surrounding liquid for extended periods at ambient conditions, opens new avenues for science and technologies that require continuous contact of solids with aqueous media. (Figure presented.).

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U2 - 10.1038/s43246-024-00555-8

DO - 10.1038/s43246-024-00555-8

M3 - Article

AN - SCOPUS:85197336903

SN - 2662-4443

VL - 5

SP - 1

EP - 10

JO - Communications Materials

JF - Communications Materials

IS - 1

M1 - 112

ER -

Predicting plastron thermodynamic stability for underwater superhydrophobicity

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Predicting plastron thermodynamic stability for underwater superhydrophobicity

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