自清洁功能的超疏水微/纳米结构铜网用于高效的分离油水（英文）

本文介绍了一种简便的方法制备n-十二烷基三甲氧基硅烷@三氧化钨包覆的超亲油超疏水的铜网.所制备的铜网显示了较为突出的超亲油和超疏水性能,该铜网的水接触角大约有154.39°,而油接触角接近于0°.实验利用了各种有机溶剂和水的混合物对所制备网膜进行分离性能测试,结果表明所得涂覆铜网的油水分离效率高达99.3V,并且水的通量大约为9962.3 L·h~(-1)·m~(-2).所制备的铜网具有良好的稳定性,经过10次分离循环后分离效率仍然保持在90%以上.由于三氧化钨优异的光催化降解性能,所制备铜网具有自清洁能力.因此,被润滑油污染的网膜可以恢复超疏水性,而这种自清洁性使所制网膜可以反复用于油水分离.     

超亲水性金属有机框架膜对油水混合物的高效分离及传质机理

化工废水大量排放和漏油、溢油事故频发对环境保护和生态平衡造成巨大的影响。本文提出了一种简单、节能、环保友好的金属有机框架膜制备方法用于油水分离。采用电化学方法在铜网上沉积金属有机框架材料获得超亲水性膜(Cu-CAT-1@铜网)。在重力驱动下，Cu-CAT-1@铜网膜能快速分离各种油/水混合物，分离效率大于95.0%，水通量大于112 kL·m^-2·h^-1。其分离性能高于大部分报道的铜网基底膜，并具有良好的重复性和可回收性。该膜传质机理主要基于Cu-CAT-1的超亲水性和水下超疏油性达到高效分离含油污水。     

超疏水膜油水分离特性实验研究

随着工业不断发展,含油废水的有效治理引起了人们的关注,寻求一种高效节能的油水分离方法迫在眉睫。本文分别以不锈钢金属丝网和不锈钢多孔板为基底,采用喷涂-高温塑化的方法制备了超疏水网膜及板膜。利用超疏水膜进行油水分离实验并探究了不同操作条件对分离效果的影响,得到当初始含油量低于50 g/L时,其对分离效率影响不大;板膜的分离效率随油水混合物流量的增加而降低,随分离压差的增大而增大;油水混合物流量对网膜分离效率的影响不大。分析机理发现,利用超疏水膜进行油水分离是基于油和水在膜层表面润湿性的差异,油能润湿表面并透过膜层,而水不能润湿表面无法透过膜层,从而实现油水分离。     

碳纳米管阵列超双疏性质的发现

用高温裂解酞菁金属络合物方法制备了几种具有不同形貌的阵列碳纳米管膜 ,并对其超疏水和超双疏性质进行了研究 .对于具有均匀长度和外径的阵列碳纳米管膜 ,文章作者发现 ,在未经任何处理时 ,其表现出超疏水和超亲油性质 ,与水的接触角为 15 8 5± 1 5° ,与油的接触角为 0± 1 0°.经氟化处理后 ,则表现出超双疏性质 ,与水和油的接触角分别为 171± 0 5°和 16 1± 1 0° .对具有类荷叶结构的阵列碳纳米管膜 ,其表面形貌与荷叶的十分接近 ,且在未经任何处理时所表现出的超疏水性也与荷叶的非常接近 ,与水的接触角为 16 6° ,滚动角为 8° .这种超疏水和超双疏性质是由表面的纳米结构以及微米结构和纳米结构的结合产生的 .这一发现为无氟超疏水表面 界面材料的研究提供了新的思路     

氧化锌纳米线耦合硅金字塔微纳复合结构的制备及其自清洁特性研究

光伏器件粉尘堆积伴随的遮光效应极其严重,可导致太阳能电池的光电转换效率降低一半以上,这是任何其他提高光伏器件性能的高新技术所不能弥补的.本文根据Cassie-Baxter理论构建出一种基于光伏器件应用的超疏水自清洁微纳复合结构,即氧化锌纳米线耦合硅金字塔.通过调控硅金字塔的尺寸和均匀性,使其尺寸效应不被遮盖以符合存在微米构型的疏水要求,同时尽量不破坏硅光伏器件绒面的减反性能.本文采用水热法在金字塔表面生长氧化锌纳米线的方案,通过系统的实验设计,首次成功地制备了符合光伏器件应用的接触角高达154?,且接触角滞后小于10?的超疏水自清洁微纳复合结构.此外,我们不仅发现硅金字塔的刻蚀存在"高温促进硅金字塔刻蚀"的温度效应和硅金字塔顶部有"圆润-方正-圆润"的时间效应,还从物理上对高温促进刻蚀、晶体的各向异性刻蚀导致的硅金字塔和我们所制备的氧化锌纳米线耦合硅金字塔复合结构的陷光效应等进行了比较充分的分析.     

接触角滞后对组合表面液滴运动的影响

本文通过控制NaOH和(NH_4)_2S_2O_8溶液的刻蚀时间,制备了具有不同接触角滞后超疏水区的0.5 mm-0.5mm超疏水疏水组合表面,可视化研究了常压纯蒸汽下液滴脱落半径,冲刷周期,尺寸分布.电镜表征结果表明,刻蚀时间越长,所制备超疏水表面的微纳结构越细,导致液滴接触角滞后增加。在0.5 mm-0.5 mm超疏水-疏水组合表面冷凝过程中,存在两种排液行为:液滴横向抽吸和液滴跨区脱落。随着超疏水区接触角滞后的增加,对液滴的抽吸作用越强。液滴跨区脱落直径随着超疏水区接触角滞后的增加有减小趋势,表面冲刷周期随超疏水区接触角滞后的增加而减小;与完全疏水表面相比,组合表面疏水区域液滴尺寸较小,主要集中在50μm以内。     

等离子体制备自修复超疏水涂层纤维

通过低温等离子体聚合交联作用,制备了基于PDMS@ZnO纳米颗粒复合涂层的超耐久、自修复超疏水涤纶纤维.研究了制备工艺对超疏水性、自修复性以及涂层的耐久性和稳定性的影响.结果显示, PET-g-PDMS@ZnO织物表面的水接触角(WCA)可达162.7°,滚动角(SA)为7.5°,经过300次水洗循环和1300次摩擦循环后仍然保持超疏水特性, WCA和SA分别为150.0°和35.0°.分别采用等离子体和加热方法对磨损破坏的涂层进行自修复处理,结果表明等离子体修复效果明显,而热修复只在小载荷下效果明显,并利用扫描电子显微镜、纳米压痕以及X射线光电子能谱测量结果探讨了自修复机理.该研究为等离子体技术在超疏水织物制备中的开发和应用提供理论和技术支撑.     

水蒸气在超疏水表面上的冷凝传热

用高温裂解法在紫铜基底上制备了疏水性碳纳米管膜,通过对此碳纳米管膜进行氟化处理,改善了表面的疏水性.在室温下,实验测得水在这种表面上的接触角在90°～130°之间.以水蒸气为冷凝介质的冷凝传热实验表明,水蒸气在超疏水纳米材料表面上能形成较好的滴状冷凝,冷凝传热膜系数可达40000 W/(m2·K).与纯粹膜状冷凝相比,冷凝传热系数提高3～4倍.分析表明,此碳纳米管膜所产生的附加热阻只占冷凝传热热阻的千分之一,对冷凝传热膜系数的影响可以忽略.     

两步法制备超疏水性ZnO纳米棒薄膜

采用两步法制备了超疏水性ZnO纳米棒薄膜,在用磁控溅射在普通玻璃衬底上生长一层ZnO籽晶层基础上,利用液相法制备了空间取向高度一致的ZnO纳米棒阵列,经修饰后由亲水性转变为超疏水性.用扫描电子显微镜观察了纳米棒的表面结构,用接触角测量仪测出水滴在ZnO纳米棒薄膜表面的接触角为151°±05°,滚动角为7°.用Cassie模型对ZnO纳米棒薄膜的超疏水性进行了验证. 关键词： ZnO纳米棒 超疏水 两步法     

面向微通道换热器的耐久性超疏水涂层调控及其抑霜性能

本研究针对微通道换热器提出了一种具有良好耐久性的超疏水涂层制备方法。首先采用一步水热法原位合成具有微纳二级粗糙结构的锌铝水滑石(Zn-Al LDH),再通过电化学沉积法在表面沉积低表面能物质。水热法制备的粗糙结构很好的保护了电化学沉积得到的低表面能薄膜,增强了超疏水涂层的耐久性。同时,电化学测试发现,基体的自腐蚀电位从-1.454 V正移至-1.2989 V,腐蚀电流密度从纯铝微通道表面的2.564×10^-3A·cm^-2降低到5.2×10^-6A·cm^-2,显示出超疏水微通道换热器具有极好的耐腐蚀性能。此外,超疏水微通道的结霜实验和模拟结果表明其具有良好的抗结霜性能。     

Controlled growth of standing Ag nanorod arrays on bare Si substrate using glancing angle deposition for self-cleaning applications

A facile approach to manipulate the hydrophobicity of surface by controlled growth of standing Ag nanorod arrays is presented. Instead of following the complicated conventional method of the template-assisted growth, the morphology or particularly average diameter and number density (nanorods cm^?2) of nanorods were controlled on bare Si substrate by simply varying the deposition rate during glancing angle deposition. The contact angle measurements showed that the evolution of Ag nanorods reduces the surface energy and makes an increment in the apparent water contact angle compared to the plain Ag thin film. The contact angle was found to increase for the Ag nanorod samples grown at lower deposition rates. Interestingly, the morphology of the nanorod arrays grown at very low deposition rate (1.2 Å?sec^?1) results in a self-cleaning superhydrophobic surface of contact angle about 157° and a small roll-off angle about 5°. The observed improvement in hydrophobicity with change in the morphology of nanorod arrays is explained as the effect of reduction in solid fraction within the framework of Cassie–Baxter model. These self-cleaning Ag nanorod arrays could have a significant impact in wide range of applications such as anti-icing coatings, sensors and solar panels.     

Facile method to prepare stable superhydrophobic Co3O4 surface

A facile and novel method was developed to fabricate rough Co₃O₄ surface with hierarchical micro- and nanostructures by the combination of simple solid state reactions and coating process. After modification with stearic acid, a superhydrophobic surface with water contact angle of 155 ± 1.8° and sliding angle of 2° was obtained. The superhydrophobic Co₃O₄ surface remained superhydrophobic property in a wide pH range from 3 to 14. The superhydrophobic Co₃O₄ surface also showed excellent self-cleaning property and high stability in ambient environments.     

Stable superhydrophobic surface with hierarchical mesh-porous structure fabricated by a femtosecond laser

Inspired by the lotus leaf, a new superhydrophobic surface with hierarchical mesh-porous structure is fabricated by femtosecond laser irradiation on silicon. The fabricated surface shows a superhydrophobic character with water contact angle being found to reach up to 158^°±1^° and sliding angle of 4^°±0.5^°. The superhydrophobicity is stable even if the PH of solution changes from 1 to 14. And the surface also exhibits excellent self-cleaning effect and bouncing behavior, implying that the adhesion of the surface is extremely low. This work will enhance further understanding of the wettability of a solid surface with special surface morphology.     

Superhydrophobic MoS2-based multifunctional sponge for recovery and detection of spilled oil

Oil spills are a major threat to the marine ecosystem, requiring immediate solutions to remove spilled oil from oceanic environments. In this study, we report a superhydrophobic molybdenum disulfide (MoS₂) coated polydimethylsiloxane (PDMS) sponge and demonstrate its high proficiency in spilled oil recovery and oil spill detection based on oil-water separation ability. This novel oil sorbent is fabricated by a simple dip-coating to incorporate MoS₂ flakes into PDMS sponge. The optimized MoS₂-sponge displays a water contact angle of >152°, demonstrating excellent superhydrophobicity and high oil absorption (>97 wt%) for a variety of oils, including vegetable oil and fuel waste. Moreover, the material retains excellent oil absorption capability upon repetitive compression cycles. The versatility of this novel sorbent has been extended for the real-time spontaneous detection of oils by taking advantage of electrically conductive MoS₂ layers.     

A stable superhydrophobic and superoleophilic Cu mesh based on copper hydroxide nanoneedle arrays

A superhydrophobic and superoleophilic copper mesh was prepared via a simple electrochemical route. Copper substrates were anodized in a 1 mol/L NaOH aqueous solution to produce a rough thin film of Cu(OH)₂ nanoneedle arrays and then the film was reacted with 1H,1H,2H,2H-perfluorooctyltriethoxysilane to form a very thin and stable hydrophobic coating layer. X-ray photoelectron spectroscopy (XPS) data revealed the coordination of silicon atoms with cuprate (CuO) molecules present on the anodized substrate. The water contact angle of the perfluoroalkylsilane-modified nanoneedle surface was approximately 170°. Furthermore, the superhydrophobicity was maintained after wet treatments in aqueous solutions with a wide pH range of 2−14 and after a long storage time of 4 months. This excellent durability and long-term reliability, which was unattainable in comparable samples modified with n-dodecanethiol or n-dodecanoic acid, could be interpreted with the formation of a stable and dense surface modification layer via a condensation reaction between -SiOEt and -CuOH and subsequent polymerization among the ethoxysilane adsorbates. Preliminary studies of the dynamic permeation behaviors of water and non-polar solvents exhibited a potential use of the hybrid copper mesh as a filtering layer for oil and water separation.     

Controllable fabrication of lotus-leaf-like superhydrophobic surface on copper foil by self-assembly

A novel approach was developed to fabricate a lotus-leaf-like superhydrophobic surface on a copper foil by simple self-assembly method with the assistance of the porous PDMS template which was used to adjust the oxidized parts of the copper foil surface before self-assembly. The results showed a series of beautiful flower-like microstructures resulting from the self-assembly of cupric stearate that were distributed at regular intervals on the as-prepared copper foil surface similar to the papillae of lotus leaf surface. The water contact angle of the as-prepared copper surface was up to 161° and its sliding angle was only 3°. Its great superhydrophobicity could be kept unchanged after 6 months in air. The formation mechanism of the lotus-leaf-like structure was discussed. This simple and low-cost method is expected to be applied to design and prepare complicated superhydrophobic surfaces with beautiful regular microstructures on different substrates such as stainless steel, zinc, and so on.     

A simple way to fabricate an aluminum sheet with superhydrophobic and self-cleaning properties

<正>A superhydrophobic aluminum sheet is fabricated via a hot water immersing process and subsequently surface modification with heptadecafluorodecyltrimethoxy-silane(HTMS).As revealed by the scan electron microscopy(SEM), X-ray diffraction(XRD),and Fourier-transform infrared spectrophotometer(FTIR) results,a rough pseudoboehmite film is formed on the aluminum sheet,and HTMS molecules are grafted on the film surface successfully.These two factors make the treated aluminum sheet present superhydrophobicity with a water contact angle larger than 160°and sliding angle less than 5°,and possess a self-cleaning property.Furthermore,the flexible superhydrophobic aluminum sheet could be pasted to a cylinder surface without destroying its superhydrophobicity.At the end,the effect of hot water treatment time on superhydrophobicity is investigated.     

通过电沉积及氟硅烷改性而成的三维铜镍复合超疏水表面

将Cu-Ni微纳米颗粒电沉积在铝基底上，通过1H、1H、2H、2H-全氟癸基三甲氧基硅烷(FAS-17)对其进行修饰，制备了超双疏(SAP)表面. 采用扫描电子显微镜、X射线衍射、能量色散X射线光谱和傅里叶变换红外光谱对其形貌和化学成分进行了研究. 结果表明，SAP表面具有三维微纳结构，最大水接触角160.0°，油接触角151.6°. 进一步测试了SAP表面的机械强度和化学稳定性，结果显示该SAP表面具有优良的耐磨性、耐酸耐碱性能、自洁性和防污性能.     

A simple solution-immersion process for the fabrication of superhydrophobic cupric stearate surface with easy repairable property

The present work reports a simple and time-saving method to fabricate cupric stearate film on zinc substrate by a solution-immersion process. Superhydrophobic surfaces are conventionally prepared employing two steps: roughening a surface and lowering its surface energy. The fabrication of superhydrophobic cupric stearate surface is reported using a one-step process by immersing a zinc plate coated with copper into the stearic acid solution, simplifying the complexity of two different steps involved in the conventional methods. The surface of the zinc plate coated with copper is found to be covered with low surface energy cupric stearate film providing the water contact angle of 160 ± 1° with the rolling off properties. In addition, the damaged superhydrophobic surface can restore superhydrophobicity property by immersing the surface into the stearic acid solution again.     

A novel and expeditious method to fabricate superhydrophobic metal carboxylate surface

This article has presented a novel method to fabricate superhydrophobic metal carboxylate surface on substrates like copper, ferrum, etc. This method markedly shortened the fabrication time to less than one second. The superhydrophobic effect is even better that the contact angle (CA) is 170±1° and the sliding angle (SA) <2°. Scanning electron microscopy (SEM) images showed micro-nano flower-like structures. Fourier transform infrared (FTIR) spectroscopy and X-ray photoelectron spectroscopy (XPS) confirmed that the flower-like structures are composed of Cu[CH₃(CH₂)₁₂COO]₂. The ethanol solution containing fatty acid and metal salt plays a key role in this method. This method has tremendous potentials in industrial production of superhydrophobic materials.