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].     

The super-hydrophobic IR-reflectivity TiO2 coated hollow glass microspheres synthesized by soft-chemistry method

The super-hydrophobic and IR-reflectivity hollow glass microspheres (HGM) was synthesized by being coated with anatase TiO₂ and a super-hydrophobic material. The super-hydrophobic self-cleaning property prolong the life time of the IR reflectivity. TBT and PFOTES were firstly applied and hydrolyzed on HGM and then underwent hydrothermal reaction to synthesis anatase TiO₂ film. For comparison, the PFOTES/TiO₂ mutual-coated HGM (MCHGM), PFOTES single-coated HGM (F-SCHGM) and TiO₂ single-coated HGM (Ti-SCHGM) were synthesized as well. The MCHGM had bigger contact angle (153°) but smaller sliding angle (16°) than F-SCHGM (contact angle: 141.2°; sliding angle: 67°). Ti-SCHGM and MCHGM both showed similar IR reflectivity with ca. 5.8% increase compared with original HGM and F-SCHGM. For the thermal conductivity, coefficients of F-SCHGM (0.0479 W/(m K)) was basically equal to that of the original HGM (0.0475 W/(m K)). Negligible difference was found between the thermal conductivity coefficients of MCHGM-coated HGM (0.0543 W/(m K)) and Ti-SCHGM (0.0546 W/(m K)).     

Extreme wettability due to dendritic copper nanostructure via electrodeposition

Dendritic copper film with convertible extreme wettability is prepared on metal surface via electrodeposition. With field emission scanning electron microscopy (FESEM), X-ray diffraction (XRD) and electrochemical measurement, the morphology, composition and formation mechanism of dendritic copper film were studied. It is found that the film is mainly composed of metallic copper. Also some residual cuprous oxide and chloride exist in the deposit. The single micron-sized dendrite consists of a main stem with side branches, on which the higher-order branches with the dimension of tens of nanometers grow. A hydrophobic modification can induce the conversion of the apparent wettability of film from super-hydrophilicity (with apparent water contact angle of 5 ± 3°) to super-hydrophobicity (with apparent water contact angle of 154.1 ± 3°), which is due to the capillary effect. The method proposed in this paper is time-saving and facile to operate, and it offers a promising technique to prepare metallic surface with a high wettability contrast for water.     

Structure and oil repellency: Textiles with liquid repellency to hexane

Combining structure and liquid repellent coatings to optimise non-wettability is a well-established field. However, the area in recent years has been dominated by data on water repellency. The work here provides data on how certain plant structures can be used to develop surfaces that provide repellency towards both polar and non-polar, low surface tension fluids. Combining fluoropolymer coatings with ‘hairy’ fibres is particularly beneficial for providing liquid-repellent textiles. None of these surfaces can however be regarded as super-repellent to low surface tension liquids (i.e. with little difference in advancing and receding contact angles).     

Macroporous fluoropolymeric films templated by silica colloidal assembly: A possible route to super-hydrophobic surfaces

A super-hydrophobic surface was obtained on a three-dimensional (3D) polyvinylidene fluoride (PVDF) macroporous film. The porous films were fabricated through self-assembled silica colloidal templates. The apparent water contact angle of the surface can be tuned from 106° to 153° through altering the sintering temperature and the diameter of the colloidal templates. A composite structure of micro-cavities and nanoholes on the PVDF surface was responsible for the super-hydrophobicity. The wettability of the porous surfaces was described by the use of the Cassie-Baxter model and Wenzel's equation.     

Improving Anti-frosting Performance for Super-hydrophobic Nanocomposite Coatings

Super-hydrophobic surfaces with water contact angle (WCA) higher than 150o have attracted great attention these years1, due to their scientific values and potential technological applications as antifouling coatings, non-sticking coatings, and so on. Alth…     

Effect of contact angle hysteresis on water droplet evaporation from super-hydrophobic surfaces

Small water drops demonstrate different evaporation modes on super-hydrophobic polymer surfaces with different hysteresis of contact angle. While on the high-hysteresis surface evaporation follows the constant-contact-diameter mode, the constant-contact-angle mode dominates on the low-hysteresis surface. These modes were previously reported for smooth hydrophilic and hydrophobic surfaces, respectively. The experimental data are compared to the previous models describing spherical cap drops that evaporate in different modes, and good fitting is obtained.     

Characteristics and self-cleaning effect of the transparent super-hydrophobic film having nanofibers array structures

Transparent super-hydrophobic films were fabricated using the PDMS method and silane process, based on anodization in phosphoric acid. Contact angle tests were performed to determine the contact angle of each film according to the anodizing time. Transmittance tests also were performed to obtain the transparency of each TPT (trimethylolpropane propoxylate triacrylate) replica film according to the anodizing time. The contact angle was determined by studying the drop shape, and the transmittance was measured using a UV-spectrometer. The contact angle increases with increasing anodizing time, because increasing pillar length can trap more air between the TPT replica film and a drop of water. The transmittance falls with increasing anodizing time because the increasing pillar length causes a scattering effect. This study shows that the pillar length and transparency are inversely proportional. The TPT replica film having nanofibers array structures was better than other films in aspect of self-cleaning by doing quantitative experimentation.     

注压成型仿生纳米结构聚丙烯表面的冷凝微水滴动态行为

选择2种锥形纳米孔结构参数不同的阳极氧化铝（AAO）作为模板,利用注射压缩成型（ICM）技术将AAO模板中的纳米孔结构复制到聚丙烯（PP）表面上,在复制的PP表面上形成了致密且规则排列的锥形纳米柱阵列结构.该结构是一种仿生蝉翼纳米结构.在纳米柱结构的润湿状态能量比和顶部直径与中心间距之比（分别约为0.46和0.26）均明显较小的PP复制物表面,冷凝微水滴呈明亮的球状;在没有外力作用下,冷凝微水滴可通过频繁地合并、跳跃从该表面上移除,表面不断更新,即该表面具有明显的冷凝微水滴自移除（CMDSR）功能,使表面上覆盖的冷凝微水滴维持明显较低的量,而且冷凝微水滴维持较小的直径（不超过40 μm）.该CMDSR功能是在未经低表面能修饰的情况下获得的.研究结果表明,利用ICM技术可快速、批量制备具有CMDSR功能的超疏水高分子材料.     

Super-hydrophobicity and oleophobicity of silicone rubber modified by CF4 radio frequency plasma

Owing to excellent electric properties, silicone rubber (SIR) has been widely employed in outdoor insulator. For further improving its hydrophobicity and service life, the SIR samples are treated by CF₄ radio frequency (RF) capacitively coupled plasma. The hydrophobic and oleophobic properties are characterized by static contact angle method. The surface morphology of modified SIR is observed by atom force microscope (AFM). X-ray photoelectron spectroscopy (XPS) is used to test the variation of the functional groups on the SIR surface due to the treatment by CF₄ plasma. The results indicate that the static contact angle of SIR surface is improved from 100.7° to 150.2° via the CF₄ plasma modification, and the super-hydrophobic surface of modified SIR, which the corresponding static contact angle is 150.2°, appears at RF power of 200 W for a 5 min treatment time. It is found that the super-hydrophobic surface ascribes to the coaction of the increase of roughness created by the ablation action and the formation of [-SiF_x(CH₃)_2−x-O-]_n (x = 1, 2) structure produced by F atoms replacement methyl groups reaction, more importantly, the formation of [-SiF₂-O-]_n structure is the major factor for super-hydrophobic surface, and it is different from the previous studies, which proposed the fluorocarbon species such as C-F, C-F₂, C-F₃, CF-CF_n, and C-CF_n, were largely introduced to the polymer surface and responsible for the formation of low surface energy.