Nanosecond laser-assisted fabrication of Ti6Al4V surfaces with gradient wettability and robust cross-linked microstructures

Journal of Physics: Conference Series Pub Date : 2024-07-01 DOI:10.1088/1742-6596/2790/1/012013

Jianli Chen, Yaohua Fan, Libo Wan, Weifeng Wu

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Abstract

Surfaces with gradient wettability outperform singular superhydrophobic surfaces in terms of self-cleaning efficiency, anti-contamination properties, and fluid manipulation. These attributes offer extensive application potential across various industrial and scientific domains. This study introduces and employs nanosecond pulsed laser ablation to create wettability gradient surfaces on Ti6Al4V alloys, featuring robust cross-linked frame microstructures. Experimental results demonstrate that by varying the ridge width (w), associated with the liquid-solid contact fraction, we can achieve varying wettability and mechanical durability in these cross-linked frame microstructures. Wettability tests indicate static contact angles ranging from 150.7° to 105.45°. Furthermore, the sandpaper linear abrasion test illustrates a decrease in material wear rate with an increase in w. Under similar test conditions, the proposed surfaces demonstrate superior mechanical durability compared to two other prevalent wettability surface structures. The proposed surfaces, efficiently and eco-friendly produced through nanosecond laser fabrication, hold tremendous potential for diverse applications.

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用纳秒激光辅助制造具有梯度润湿性和坚固交联微结构的 Ti6Al4V 表面

具有梯度润湿性的表面在自清洁效率、抗污染性能和流体操控方面优于单一的超疏水表面。这些特性为各种工业和科学领域提供了广泛的应用潜力。本研究介绍并采用纳秒脉冲激光烧蚀技术，在 Ti6Al4V 合金上形成具有坚固交联框架微结构的润湿性梯度表面。实验结果表明，通过改变与液固接触部分相关的脊宽（w），我们可以在这些交联框架微结构中实现不同的润湿性和机械耐久性。润湿性测试表明，静态接触角从 150.7° 到 105.45°不等。此外，砂纸线性磨损测试表明，材料磨损率随着 w 的增加而降低。在类似的测试条件下，与其他两种普遍的润湿性表面结构相比，所提出的表面具有更高的机械耐久性。通过纳秒激光制造技术高效、环保地生产出的拟议表面在各种应用领域具有巨大潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Physics: Conference Series

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