树莓状超疏水多孔复合棉纤维的制备及油水分离性能

基于聚多巴胺（PDA）的化学性质和树莓状纳米粒子的粗糙结构,以聚多巴胺包覆的棉纤维为基底,制备了具有多重粗糙度的树莓状超疏水多孔复合棉纤维材料.通过扫描电子显微镜观察树莓状超疏水多孔复合棉纤维表面的微观形貌,PDA-SiO₂纳米粒子稳定地固定在聚多巴胺涂覆的棉纤维表面.经过氟化改性的树莓状超疏水多孔复合棉纤维具有超疏水性,水接触角为158.2°,油接触角为0°.油/水分离实验结果表明,树莓状超疏水多孔复合棉纤维对己烷/水混合物的分离效率可达99.4%以上,使用20次后仍维持较高的分离效率.同时,其具有较高的溶剂吸附能力（13~34 g/g）、重复使用性及机械稳定性,吸油能力可与硅气凝胶相媲美.     

超疏水超亲油铜网的制备及其在油水分离中的应用

以铜网为基底,通过浸涂法在其表面制得超疏水超亲油有机-无机复合薄膜,水滴、油滴在其表面的接触角分别为152°和10°。 线性低密度聚乙烯-SiO₂纳米球构成的复合阶层结构及低表面能线性低密度聚乙烯涂层的协同作用使铜网产生独特的润湿性。 该铜网具有很好的自清洁性和抗腐蚀性,可用于油水混合物的有效分离。 与传统方法相比,该方法制备超疏水-超亲油薄膜方法简单、成本低、无氟,有望在实践中得到应用。     

PVA-SiO_2复合物改性棉纤维及其吸油性能

首先以棉纤维为主要原材料,通过一步浸渍将聚乙烯醇-二氧化硅粒子(PVA-SiO_2)复合物涂覆在棉纤维表面;然后对其进行疏水改性,制得一种超疏水吸油材料。通过扫描电子显微镜(SEM)和水接触角(WCA)测试对改性纤维的表面结构及润湿性进行了分析表征。研究了PVA和SiO_2纳米粒子的质量分数对纤维吸油性能的影响,并评价了改性纤维的疏水性、润湿耐受性、吸油速率和重复使用性能。结果表明:棉纤维经过PVA-SiO_2复合物涂覆后具有稳定的超疏水性,吸油量比改性前显著提高,对正己烷、甲苯和氯仿的吸油量分别提高了47%、18.6%和26.2%。     

超疏水滤纸的制备与应用

对SiO2纳米粒子进行硅烷化改性,再将其修饰到滤纸上,制备出静态水接触角＞150°的超疏水滤纸,对制备条件进行了优化。 用热重分析及扫描电子显微镜对超疏水滤纸表征后发现,二氧化硅纳米粒子在滤纸纤维表面形成一层包裹层,即纳米级粗糙结构,这种结构对滤纸的疏水性具有关键作用。 对滤纸的油水分离性能进行了研究,发现其对非均相体系和高粘度油水混合物具有很好的分离效果。     

Zn片经水热反应和氟硅烷修饰构建超疏水ZnO表面

以乙二胺为溶剂, Zn片在120、140 及160 ℃经水热反应生长出具有蛋糕形、荷叶乳突状、棒状和仙人球状等微结构的ZnO表面. 扫描电镜研究表明, 反应时间越长越有利于形成完整的微纳米结构, 反应温度较高生成的微纳米结构更规整. 140 ℃反应4 h和160 ℃反应5 h的ZnO表面经过氟硅烷修饰后表现出良好的超疏水性, 与水滴的接触角分别达到154.6°和157.3°, 滚动角分别为5°和3°. 该方法因其操作简便、成本低廉, 在锌表面制备特殊微结构和构建超疏水表面具有潜在的应用.     

超疏水棉花的制备及用于油水分离

采用溶胶-凝胶法制备了SiO2水溶胶,并用三甲基甲氧基硅烷进行疏水改性,通过一步浸泡法将改性后SiO2水溶胶修饰到棉花上制备出改性棉花,用接触角测定仪和扫描电子显微镜对制备的改性棉花进行了表征,二次蒸馏水及酸、碱液滴在改性棉花上的接触角均大于150°,表明制备的改性棉花具有超疏水性和耐酸碱性。 改性棉花对柴油展示了高达8.3 g/g的饱和吸附量,在5次重复使用中,吸附能力和接触角均可维持在4.0 g/g和大于150°水平。 在油水混合物吸附研究中,改性棉花吸水量仅是未改性棉花吸水量的1/45,表明改性棉花对油具有很好的选择性。 吸附了柴油后的改性棉花经过简单挤压,即可直接回收吸附的柴油和释放出改性棉花,从而实现了改性棉花的重复使用。     

溶液浸泡结合表面涂层制备超疏水-超疏油表面

超疏水-超疏油材料在防污、防水、防油等领域有广泛的应用前景而引起人们极度关注。 本文用全氟辛酸溶液浸泡锌粉制得超疏水-超疏油锌粉,用聚乙烯醇胶将超疏水-超疏油锌粉粘合、固定到玻璃、木头、塑料、不锈钢、纸片、石头表面后可制得超疏水-超疏油表面,水滴、油滴在其表面的接触角均超过150°。 锌粉与全氟辛酸反应后生成Zn[CF₃(CF₂)₆COO]₂,氟代长链烷基的低表面能化学组成与微纳米粗糙结构的协调作用使其表现出超疏水、超疏油性能。 相关研究有望为超双疏材料的设计、制备及其在自清洁、防水防油及抗污等领域的应用提供借鉴。     

直接浸泡法构筑纯铜的超疏水表面

以棕榈酸-乙醇溶液为疏水剂,利用直接浸泡法在纯铜表面上构筑了超疏水薄膜。 纯铜表面超疏水薄膜的最佳制备条件为：0.03 mol/L棕榈酸-乙醇溶液,室温（20～22 ℃）,浸泡144 h。 通过扫描电子显微镜、接触角测量仪、红外光谱仪和高精密电子天平对超疏水表面进行了表征和分析。 实验结果表明,纯铜试样表面形成了100～200 μm大小的草状棕榈酸铜微簇,接触角达到了150°,其具有较好的抗结垢性能。     

尼龙表面的超疏水及高度疏油改性

在聚合物表面引入多级粗糙结构并降低表面能可以提高其表面的疏水疏油性. 采用三种不同方法在尼龙6(聚酰胺)表面引入活性基团, 即或将尼龙6材料表面的酰胺键还原成仲胺, 或硅羟基化, 或使用低温等离子体处理得到羟基, 并通过X-射线光电子能谱(XPS)进行验证. 实验结果表明, 表面含有仲胺基团的尼龙6可静电吸附硅球; 而表面含有硅羟基及羟基的尼龙6可原位生长纳米硅层, 再经过3-氨基丙基三甲氧基硅烷(APS)处理可达到硅球吸附的目的. 经比较了不同改性方法对在尼龙6表面构建粗糙结构的影响, 我们认为等离子体处理更利于方便快捷地制备稳定均匀的粗糙结构. 当被全氟十二烷基三氯硅烷(Rf-Si)氟化修饰后, 具有粗糙结构的尼龙6表面均具有超疏水性, 但其疏油性则与表面引入的硅球尺寸密切相关, 如在500～900 nm硅球构建的粗糙表面上, 十六烷烃(3 μL)的静态接触角为140°左右, 滚动角为20°; 而在20～200 nm硅球构建的粗糙表面上, 其静态接触角和滚动角则分别为125°和40°左右. 实验结果还显示, 这类具有一定双疏性的尼龙表面也有较好的抗细菌粘附性.     

CaCO_3颗粒模板法制备聚合物超亲水/超疏水表面

以碳酸钙(CaCO3)颗粒层为模板,运用简单的热压和酸蚀刻相结合的方法制备聚合物超亲水/超疏水表面.首先在玻璃基底上均匀铺撒一层CaCO3颗粒,以此作为模板,通过热压线性低密度聚乙烯(LLDPE)使CaCO3颗粒均匀镶嵌在聚合物表面,获得了超亲水性质;进一步经酸蚀得到了具有微米和亚微米多孔结构的表面,其水滴静态接触角(WCA)可达(152.7±0.8)°,滚动角小于3°,具备超疏水性质.表面浸润性能和耐水压冲击性能研究表明该超疏水表面具有良好的稳定性和持久性.用同样工艺微模塑/酸蚀刻其它疏水性聚合物,得到类似结果.     

阵列聚合物纳米柱膜的超疏水性研究

浸润性(又称润湿性,Wettability)是固体表面的一个重要特征,它主要由表面化学组成和表面的几何结构两方面控制^[1～5].近年来,超疏水性固体表面由于在防雪、防污染、抗氧化以及防止电流等方面都有非常广阔的应用前景,引起了人们的极大关注[6～11].     

表面修饰引发的ZnO纳米棒阵列膜的超疏水性

润湿性是固体表面的重要性质之一 ,它受控于固体表面自由能和表面粗糙度的大小 ,一般可用液体在固体表面接触角的大小来衡量 .由于水与超疏水表面 (水与固体表面的接触角大于 1 5 0°的表面 )的接触面积很小 ,通过水所发生的化学发应和化学键的形成受到限制 ,使这种表面具有防水、防污染和防氧化等多种功能 ,因而备受人们的关注 [1～ 6 ] .作为宽禁带半导体材料 ,Zn O以其独特的光电和催化等性质在短波激光器、气体传感器、高效催化剂、太阳能电池等方面具有广阔的应用前景 .表面润湿性的研究对于将 Zn O用于各种器件非常重要 .Pesika等 […     

硅烷表面修饰引发的ZnO微米棒膜的超疏水性

采用简单的低温水热法制备出ZnO微米棒薄膜,其经辛基三甲氧基硅烷和十二氟庚基丙基三甲氧基硅烷修饰后显示出超疏水性,静态接触角分别为(150±1.3)°和(155±1.5)°,滚动角依次为5°和3°。 ZnO微米棒的微结构和低表面能材料辛基三甲氧基硅烷、十二氟庚基丙基三甲氧基硅烷的表面修饰是其显示超疏水性的原因,用Cassie理论对膜的润湿性进行了分析。     

铝合金表面原位自组装超疏水膜层的制备及耐蚀性能

采用阳极氧化法在铝合金表面原位构造粗糙结构, 经表面自组装硅氧烷后得到超疏水自清洁表面, 与水滴的接触角最大可达157.5°±2.0°, 接触角滞后小于3°. 通过傅立叶变换红外(FT-IR)光谱分析仪、场发射扫描电子显微镜(FE-SEM)、能谱仪(EDS)、原子力显微镜(AFM)和接触角测试对阳极氧化电流密度、硅氧烷溶液中水的含量和自组装时间等参数进行了分析, 并得到制备超疏水自清洁表面的最优工艺参数. FE-SEM及AFM的测试结果表明, 由自组装硅氧烷膜层的无序性形成的纳米结构和阳极氧化构造的微米级粗糙结构与硅氧烷膜层的低表面能的协同作用构成了稳定的超疏水表面. 电化学测试(动电位极化)的结果表明, 原位自组装超疏水膜层极大地提高了铝合金的耐蚀性.     

Fabrication of superhydrophobic sponge with hierarchical structure and application for oil/water separation

Oil/water separation polyurethane sponge with hierarchically structured surface similar to the chemical/topological structures of lotus leaf has been successfully developed by combining mussel-inspired one-step copolymerization approach. The chemical structure, surface topography, and surface wettability of the sponge were characterized by FTIR, SEM, and contact angle experiments, respectively. The results showed that as-prepared sponge exhibited high oil absorption rate because of the expansion in oil and collapse in water of the polymer molecular brushes. Meanwhile, it also possessed high absorption capacity (20 times of the self-weight), high oil retention (93.7%), and good recyclability. It had excellent potential in practical applications.     

Cathodic etching for fabrication of super-hydrophobic aluminum coating with micro/nano-hierarchical structure

A facile method for fabricating super-hydrophobic surfaces on the magnetron sputtering aluminum film by cathodic electrochemical etching followed by the modification of myristic acid was presented in this article. The morphologies and the compositions of the films were characterized by means of scanning electron microscopy (SEM), Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS), respectively. The corrosion behavior of the super-hydrophobic film was evaluated by potentiodynamic polarization measurement, linear polarization measurement, and electrochemical impedance spectroscopy. After the treatment with cathodic electrochemical etching, the thin aluminum film remained unbroken and the bulk structure of the aluminum coating maintained a microcrystalline morphology while the surface of the coating presented a petal-shaped microstructure dotted with nano-sized floccules. Aluminum myristate was formed on the nano/microstructural surface of the coating when the sample was modified in melting myristic acid. The static water contact angle on the surface was larger than 165°, which demonstrated that a super-hydrophobic film was prepared on the magnetron sputtering aluminum coating. The corrosion resistance of the aluminum coating was enhanced remarkably because of the super-hydrophobic modification.     

Super-hydrophobic, highly adhesive, polydimethylsiloxane (PDMS) surfaces

Super-hydrophobic surfaces have been fabricated by casting polydimethylsiloxane (PDMS) on a textured substrate of known surface topography, and were characterized using contact angle, atomic force microscopy, surface free energy calculations, and adhesion measurements. The resulting PDMS has a micro-textured surface with a static contact angle of 153.5° and a hysteresis of 27° when using de-ionized water. Unlike many super-hydrophobic materials, the textured PDMS is highly adhesive, allowing water drops as large as 25.0 μL to be inverted. This high adhesion, super-hydrophobic behavior is an illustration of the "petal effect". This rapid, reproducible technique has promising applications in transport and analysis of microvolume samples.     

Analysis of the acid and alkali resistance of superhydrophobic paper mulch

Agricultural paper mulch is an indispensable part of modern agriculture. It had the functions of heat preservation, moisture preservation, insect resistance, disease prevention, and weed growth inhibition. In order to extend the service life of the paper mulch, we use the solution immersion method to modify the surface of the paper mulch. A super-hydrophobic paper mulch is mainly prepared by using hydrophobic silica. The static contact angle of the super-hydrophobic paper mulch with water is 160.6°. The super-hydrophobic paper mulch samples were immersed in acid solution (pH?=?4.6 H₂SO₄) and alkaline solution (pH?=?8.5 NaOH). The main instruments are contact angle tester, tensile testing machine and high-speed camera. The hydrophobic properties, mechanical properties and rebound properties of the two kinds of paper mulches were compared. The results showed that the tensile strength and droplet bounce height of the superhydrophobic paper mulch decreased after being soaked in acid or alkaline solution for 48 h. The mass loss rate of paper mulch was more significant in acid solution, but its contact angle was still greater than 145°, and it had good bounce performance. After observing the microscopic morphology of its surface, it was found that silica had a micro-rough structure on the surface of the paper mulch. The method was simple and environmentally friendly, and can alleviate the problem of poor acid and alkali corrosion resistance of the paper mulch, and had extraordinary significance for environmental protection.