Smart mechanically tunable surfaces with shape memory behavior and wetting-programmable topography

This contribution reports for the first time on fabrication and investigation of wetting properties of structured surfaces containing lamellae with an exceptionally high aspect ratio - height/width ratio demonstrated of 57:1. The lamellar surface was made using a polymer with tunable mechanical prop...

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Bibliographic Details
Published inarXiv.org
Main Authors Constante, Gissela, Apsite, Indra, Auerbach, Paul, Aland, Sebastian, Schönfeld, Dennis, Pretsch, Thorsten, Milkin, Pavel, Ionov, Leonid
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 04.01.2022
Subjects
Deformation
Droplets
Formability
Heat treatment
Heating
High aspect ratio
High temperature
Lamellar structure
Low temperature
Mechanical properties
Microfluidic devices
Polymers
Room temperature
Shape memory
Topography
Transition temperature
Valves
Wetting
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Summary:This contribution reports for the first time on fabrication and investigation of wetting properties of structured surfaces containing lamellae with an exceptionally high aspect ratio - height/width ratio demonstrated of 57:1. The lamellar surface was made using a polymer with tunable mechanical properties, and shape-memory behavior. It was found that wetting properties of such structured surfaces depend on temperature and thermal treatment history - lamellae are wetted easier at elevated temperature or after cooling to room temperature when the polymer is soft because of the easier deformability of lamellae. The shape of lamellae deformed by droplets can be temporarily fixed at low temperature and remains fixed upon heating to room temperature. Heating above the transition temperature of the shape-memory polymer restores the orginal shape. The high aspect ratio allows tuning of geometry not only manually, as it is done in most works reported previously, but can also be made by a liquid droplet and is controlled by temperature. The liquid in combination with thermoresponsive topography present a new kind of wetting behavior. Moreover, the mechanical properties can be controlled - the polymer can either be hard or soft at room temperature depending on thermal pre-history. This behavior opens new opportunities for the design of novel smart elements for microfluidic devices such as smart valves, whose state and behavior can be switched by thermal stimuli: valves can or cannot be opened, are able to close or can be fixed in an open or closed states.
ISSN:2331-8422