Influence of laser surface texturing on a low‐adhesion and superhydrophobic aluminium alloy surface

Li, Jing; Fan, Fengyu; Zhao, Yanhui; Zhou, Yingluo; Li, Hong; Yu, Huadong

doi:10.1049/mnl.2017.0563

Cited by 11 publications

(2 citation statements)

References 22 publications

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“…Accordingly, the superhydrophobicity of the lotus surface is related to the surface morphology and topography, indicating that the key to varying the wetting state of a surface is to modify surface roughness [4]. The features of superhydrophobic surfaces can be used to improve the performance of new technology through corrosion prevention, [5] self-cleaning [4], antiicing [6], enhancing heat transfer [7], and chemical sensing [8][9][10]. The reported techniques and methods used to mimic the microstructure found in nature on the metal surface include the following: a femtosecond laser [11], anodization [12], an electrospray [13], photolithography [14,15], physical/chemical deposition [16], chemical etching [17], electrochemical etching [18,19], and pico/nanosecond laser devices.…”

Section: Introductionmentioning

confidence: 99%

Tuning the Wettability of a High-Strength Aluminum Alloy Using a Picosecond Laser and Stearic Acid Coating

Qahtani,

Shrotriya

2023

Coatings

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Imitating microstructures found in nature—such as lotus leaves and Namib beetles—is revolutionary in the field of surface science. Low-energy surfaces, when combined with different topographies, create different wetting states. Understanding the correlation between microstructure geometry and the behavior of water droplets is key to varying the contact angles on a low-energy surface. Here, a picosecond laser was used to modify the microtexture of aluminum alloy surfaces. Various microstructures were formed on the same surface, including the Laser-Induced Periodic Surface Structure (LIPSS), dual micro/nano hierarchical structures, and periodic arrays of a micropattern structure. Coating these microstructures with stearic acid was found to contribute to decreasing surface energy. The 92% fraction of the laser-machined to non-machined surface, when associated with different microgroove depths, created the capacity to form a superhydrophobic surface. Water droplets on a modified surface were transferred from hydrophilic at the Wenzel state to hydrophobic at the Cassie–Baxter state to a superhydrophobic state at microgroove depths ranging between 2.50 μm to 0.3 μm. The air pockets trapped in the microgrooves and nanocavities were found to subsidize the initiation of the composite interface underneath the water droplet.

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Section: Introductionmentioning

confidence: 99%

Tuning the Wettability of a High-Strength Aluminum Alloy Using a Picosecond Laser and Stearic Acid Coating

Qahtani,

Shrotriya

2023

Coatings

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“…Our research group has long been committed to the study of functional surfaces of metals. By electrodeposition of nickel, laser etching, , and electroplating of copper on the surface of aluminum, carbon steel, stainless steel, and copper, we have obtained structures with various scales and morphology and measured the wettability and corrosion resistance at various temperatures. Based on that established research foundation, this paper adopts the laser texturing method to process copper surfaces by constructing an optimal biomimetic morphology and structure.…”

Section: Introductionmentioning

confidence: 99%

Superhydrophobic Copper Surface Textured by Laser for Delayed Icing Phenomenon

Zhou

Wang

et al. 2020

Langmuir

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Inspired by the superhydrophobicity of animal and plant surfaces (via the lotus effect and petal effect), two microstructures were prepared on the surface of T2 copper by laser texturing. The two-dimensional and three-dimensional morphologies of the sample surfaces were characterized with a scanning electron microscope and a laser scanning confocal microscope, respectively. Chemical composition, wettability, and delayed icing performance were characterized with energy-dispersive spectroscopy, contact angle measurement, and cryogenic freezing, respectively. The surfaces of the two samples had different closed-pore lattice structures. The maximum static contact angle of water on either surface was 155° without any chemical modification of the surfaces. The two superhydrophobic surfaces with different substrate roughnesses exhibited different adhesion characteristics to water. The icing test showed that both surfaces had a significantly delayed icing effect relative to the untreated sample. Based on the one-dimensional heat transfer model of a water droplet in the icing phase transition, the influence of surface morphology on delayed icing characteristics was analyzed. This work provides a simple and effective method for preparing superhydrophobic copper surfaces and theoretical guidance for anti-icing applications of copper metal in low-temperature environments.

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Mechanical Stability of Fabricated Superhydrophobic Aluminium Alloy and Enhancement of Its Oleophobic Characteristics

Raj

Kango

Sandhu

2020

Lecture Notes on Multidisciplinary Industrial Engineering

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Influence of laser surface texturing on a low‐adhesion and superhydrophobic aluminium alloy surface

Cited by 11 publications

References 22 publications

Tuning the Wettability of a High-Strength Aluminum Alloy Using a Picosecond Laser and Stearic Acid Coating

Tuning the Wettability of a High-Strength Aluminum Alloy Using a Picosecond Laser and Stearic Acid Coating

Superhydrophobic Copper Surface Textured by Laser for Delayed Icing Phenomenon

Mechanical Stability of Fabricated Superhydrophobic Aluminium Alloy and Enhancement of Its Oleophobic Characteristics

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