超疏水纳米涂层技术研究进展及应用
Research progress and application of superhydrophobic nano-coating technology
任国瑜 1妥云 2郑文杰 2谯泽庭 3任壮壮 3赵娅莉 3尚军飞 3陈晓东 2高祥虎4
作者信息
- 1. 榆林学院化学与化工学院,陕西 榆林 719000;陕西榆能精细化工材料有限公司,陕西 榆林 719000
- 2. 榆林学院化学与化工学院,陕西 榆林 719000
- 3. 陕西榆能精细化工材料有限公司,陕西 榆林 719000
- 4. 中国科学院兰州化学物理研究所清洁能源化学与材料实验室,甘肃兰州 730000
- 折叠
摘要
受自然界荷叶、玫瑰花瓣等植物超疏水现象启发,超疏水涂层在自清洁、油水分离、防冰等领域被广泛应用.然而,传统超疏水涂层依赖于其表面微观粗糙结构和特殊涂层材料,制备工艺复杂,耐久性差,防腐蚀性能不足.超疏水纳米涂层由于其独特的形貌和功能,使超疏水涂层变得多功能、通用、耐用、高效.本文综述了近些年来不同纳米材料超疏水涂层的设计与制备,针对不同超疏水纳米涂层的优缺点进行了评述,并简述了其在各个领域的潜在应用,如防菌、传感器、微流体、催化等.最后,本文指出了关于使用纳米技术的超疏水涂层的最新发展和未来趋势,通过对其新颖的制备策略和对其独特性质的研究为该领域的研究人员提供一定的理论和技术参考,推进超疏水纳米涂层在诸多领域的应用.
Abstract
Inspired by natural phenomena such as the lotus leaf and rose petal,superhydrophobic coatings have found widespread applications in areas such as self-cleaning,oil-water separation and anti-icing.However,traditional superhydrophobic coatings rely on surface microscale roughness and specialized coating materials,resulting in complex fabrication processes,poor durability and inadequate corrosion resistance.In contrast,superhydrophobic nano-coatings,due to their unique morphology and functionality,offer multifunctionality,universality,durability and high efficiency.This article provided an overview of the design and fabrication of superhydrophobic nano-coatings using various nanomaterials in recent years.It evaluated the strengths and weaknesses of different superhydrophobic nano-coatings and briefly outlined their potential applications in various fields,such as antimicrobial surfaces,sensors,microfluidics,catalysis and more.Finally,the article presented the latest developments and future trends in the use of nanotechnology for superhydrophobic coatings.By exploring innovative fabrication strategies and investigating the unique properties of these coatings,this review aimed to provide researchers in the field with valuable theoretical and technical insights,promoting the widespread application of superhydrophobic nano-coatings across multiple domains.
关键词
粗糙结构/超疏水纳米涂层/耐久性/防腐蚀/纳米材料/传感器/微流体/催化Key words
rough structure/superhydrophobic nanocoating/durability/corrosion resistance/nanomaterials/sensors/microfluidics/catalysis引用本文复制引用
基金项目
国家自然科学基金(21968036)
榆林学院校内配套经费项目(22RCXM02)
榆林市高新区产学研项目(CXY2021-12)
榆林市高新区产学研项目(YGXKG-2022-102)
榆林市科技局产学研项目(CXY2022-80)
中国科学院洁净能源创新研究院-榆林学院联合基金(YLU-DNL2022005)
中国科学院洁净能源创新研究院-榆林学院联合基金(2021007)
中国科学院洁净能源创新研究院-榆林学院联合基金(2021016)
出版年
2024
国家科技期刊平台
NSTL
万方数据