Projects per year
Abstract
Wetting is typically defined by the relative liquid to solid surface tension/energy, which are composed of polar and nonpolar subcontributions. Current studies often assume that they remain invariant, that is, surfaces are wetting-inert. Complex wetting scenarios, such as adaptive or reactive wetting processes, may involve time-dependent variations in interfacial energies. To maximize differences in energetic states, we employ low-energy perfluoroalkyls integrated with high-energy silica-based polar moieties grown on low-energy polydimethylsiloxane. To this end, we tune the hydrophilic-like wettability on these perfluoroalkyl-silica-polydimethylsiloxane surfaces. Drop contact behaviors range from invariantly hydrophobic at ca. 110° to rapidly spreading at ca. 0° within 5 s. Unintuitively, these vapor-grown surfaces transit toward greater hydrophilicity with increasing perfluoroalkyl deposition. Notably, this occurs as sequential silica-and-perfluoroalkyl deposition also leaves behind embedded polar moieties. We highlight how surfaces having such chemical heterogeneity are inherently wetting-reactive. By creating an abrupt wetting transition composed of reactive and inert domains, we introduce spatial dependency. Drops contacting the transition spread before retracting, occurring over the time scale of a few seconds. This phenomenon contradicts current understanding, exhibiting a uniquely (1) decreasing advancing contact angle and (2) increasing receding contact angle. To explain the behavior, we model such time- and space- dependent reactive wetting using first order kinetics. In doing so, we explore how reactive and recovery mechanisms govern the characteristic time scales of spreading and retracting sessile drops.
Original language | English |
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Pages (from-to) | 13562–13572 |
Journal | Langmuir |
Volume | 40 |
Issue number | 26 |
DOIs | |
Publication status | Published - 14 Jun 2024 |
MoE publication type | A1 Journal article-refereed |
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Dive into the research topics of 'Polarity-Induced Reactive Wetting : Spreading and Retracting Sessile Water Drops'. Together they form a unique fingerprint.Projects
- 2 Active
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Wong William: Enhanced Electrocatalysis via the Plastron Effect
Wong, W. (Principal investigator), Koochak, P. (Project Member) & Alikhanifaradonbeh, R. (Project Member)
01/09/2022 → 31/08/2025
Project: Academy of Finland: Other research funding
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SuperElectro: Super(de)wettability-enhanced Electrocatalysis
Ras, R. (Principal investigator) & Wong, W. (Project Member)
01/05/2022 → 31/10/2025
Project: EU: MC
Equipment
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OtaNano - Nanomicroscopy Center
Seitsonen, J. (Manager) & Rissanen, A. (Other)
OtaNanoFacility/equipment: Facility