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Main Authors: Hauer, Lukas, Naga, Abhinav, Badr, Rodrique G. M., Pham, Jonathan T., Wong, William S. Y., Vollmer, Doris
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.05571
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author Hauer, Lukas
Naga, Abhinav
Badr, Rodrique G. M.
Pham, Jonathan T.
Wong, William S. Y.
Vollmer, Doris
author_facet Hauer, Lukas
Naga, Abhinav
Badr, Rodrique G. M.
Pham, Jonathan T.
Wong, William S. Y.
Vollmer, Doris
contents Silicone is frequently used as a model system to investigate and tune wetting on soft materials. Silicone is biocompatible and shows excellent thermal, chemical, and UV stability. Moreover, the mechanical properties of the surface can be easily varied by several orders of magnitude in a controlled manner. Polydimethylsiloxane (PDMS) is a popular choice for coating applications such as lubrication, self-cleaning, and drag reduction, facilitated by low surface energy. Aiming to understand the underlying interactions and forces, motivated numerous and detailed investigations of the static and dynamic wetting behavior of drops on PDMS-based surfaces. Here, we recognize the three most prevalent PDMS surface variants, namely liquid-infused (SLIPS/LIS), elastomeric, and liquid-like (SOCAL) surfaces. To understand, optimize, and tune the wetting properties of these PDMS surfaces, we review and compare their similarities and differences by discussing (i) the chemical and molecular structure, and (ii) the static and dynamic wetting behavior. We also provide (iii) an overview of methods and techniques to characterize PDMS-based surfaces and their wetting behavior. The static and dynamic wetting ridge is given particular attention, as it dominates energy dissipation, adhesion, and friction of sliding drops and influences the durability of the surfaces. We also discuss special features such as cloaking and wetting-induced phase separation. Key challenges and opportunities of these three surface variants are outlined.
format Preprint
id arxiv_https___arxiv_org_abs_2404_05571
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Wetting on Silicone Surfaces
Hauer, Lukas
Naga, Abhinav
Badr, Rodrique G. M.
Pham, Jonathan T.
Wong, William S. Y.
Vollmer, Doris
Soft Condensed Matter
Silicone is frequently used as a model system to investigate and tune wetting on soft materials. Silicone is biocompatible and shows excellent thermal, chemical, and UV stability. Moreover, the mechanical properties of the surface can be easily varied by several orders of magnitude in a controlled manner. Polydimethylsiloxane (PDMS) is a popular choice for coating applications such as lubrication, self-cleaning, and drag reduction, facilitated by low surface energy. Aiming to understand the underlying interactions and forces, motivated numerous and detailed investigations of the static and dynamic wetting behavior of drops on PDMS-based surfaces. Here, we recognize the three most prevalent PDMS surface variants, namely liquid-infused (SLIPS/LIS), elastomeric, and liquid-like (SOCAL) surfaces. To understand, optimize, and tune the wetting properties of these PDMS surfaces, we review and compare their similarities and differences by discussing (i) the chemical and molecular structure, and (ii) the static and dynamic wetting behavior. We also provide (iii) an overview of methods and techniques to characterize PDMS-based surfaces and their wetting behavior. The static and dynamic wetting ridge is given particular attention, as it dominates energy dissipation, adhesion, and friction of sliding drops and influences the durability of the surfaces. We also discuss special features such as cloaking and wetting-induced phase separation. Key challenges and opportunities of these three surface variants are outlined.
title Wetting on Silicone Surfaces
topic Soft Condensed Matter
url https://arxiv.org/abs/2404.05571