Superhydrophobic Coating Bioinspired on Rice Leaf: A First Attempt to Enhance Erosion Resistance Properties at Environmental Conditions with Ceramic Particles

Rius-Ayra, Oriol; Castellote-Alvarez, Roger; Escobar, Ana M.; Llorca-Isern, Núria

doi:10.4028/www.scientific.net/msf.941.1874

Cited by 6 publications

(2 citation statements)

References 16 publications

(17 reference statements)

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“…At the same time, under the assumption that the droplets are completely wetted, the large energy barrier formed by the chemical composition and geometry will make it difficult for the droplets to roll. This contradicts the phenomenon that droplets are easy to roll on the superhydrophobic surfaces such as lotus leaves in nature (Nuraje et al, 2013;Rius-Ayra et al, 2018). Seo and Kim.…”

Section: Wenzel Modelmentioning

confidence: 95%

Biology and nature: Bionic superhydrophobic surface and principle

Ge-Zhang

Cai

Yang

et al. 2022

Front. Bioeng. Biotechnol.

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Nature is the source of human design inspiration. In order to adapt to the environment better, creatures in nature have formed various morphological structures during billions of years of evolution, among which the superhydrophobic characteristics of some animal and plant surface structures have attracted wide attention. At present, the preparation methods of bionic superhydrophobic surface based on the microstructure of animal and plant body surface include vapor deposition, etching modification, sol-gel method, template method, electrostatic spinning method and electrostatic spraying method, etc., which have been used in medical care, military industry, shipping, textile and other fields. Based on nature, this paper expounds the development history of superhydrophobic principle, summarizes the structure and wettability of superhydrophobic surfaces in nature, and introduces the characteristics differences and applications of different superhydrophobic surfaces in detail. Finally, the challenge of bionic superhydrophobic surface is discussed, and the future development direction of this field is prospected.

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Section: Wenzel Modelmentioning

confidence: 95%

Biology and nature: Bionic superhydrophobic surface and principle

Ge-Zhang

Cai

Yang

et al. 2022

Front. Bioeng. Biotechnol.

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“…As manifested by various researchers, surfaces with extreme wettabilities, especially those with a superhydrophobic surface, can effectively enhance the erosion resistance of materials [48][49][50]. Thus, in the past few decades, laser surface texturing has also been utilized for fabrication of erosion-resistant surfaces.…”

Section: Introductionmentioning

confidence: 99%

Laser Texturing for Superwetting Titanium Alloy and Investigation of Its Erosion Resistance

et al. 2021

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Erosion of materials is one of the major causes that lead to the malfunction of equipment and facilities, and surface texturing can be a solution for enhancement of erosion resistance. In this work, superwetting (superhydrophilic/superhydrophobic) titanium (Ti) alloy surface with periodic microstructure was prepared by a facile laser-based surface texturing approach which combines laser surface texturing and low-temperature annealing. The effect of laser-induced surface texture and wettability on the erosion resistance of the laser textured surface was studied. Scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) were used to analyze the chemical surface microstructure and surface on the untreated and laser textured surfaces. The hardness and contact angle of the untreated surface, superhydrophilic surface and superhydrophobic surface were measured by microhardness tester and contact angle goniometer. Using an in-house built erosion experimental setup, the erosion resistance of the untreated surface, superhydrophilic surface and superhydrophobic surface was investigated. The experimental results demonstrate that micro-bumps are formed after laser surface texturing. In the meantime, the surface hardness for the laser textured surface with a step size of 150 μm is increased by 48% under the load of 1.961 N. Compared with the untreated surface, the erosion resistance is increased by 33.9%, 23.8% and 16.1%, respectively, for the superhydrophobic surface. The SEM results show that the untreated surface has large and deep impact pits, while the superhydrophobic surface only has small and shallow impact pits, indicating that the erosion process resulted in less damage to the substrate. The EDS results shows that superhydrophobicity plays a critical role in protecting the substrate from erosion. It is thus believed that the superhydrophobic surface has pronounced effects for improving the hardness and erosion resistance of Ti alloy.

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