热塑性淀粉材料的表面疏水化反应

用反应性试剂 (TDI/蓖麻油预聚体 )对热塑性淀粉材料 (TPS)表面进行了疏水化处理。研究了预聚体与 TPS表面的反应性、涂层的疏水性能以及涂层的形貌。红外光谱 (IR)分析结果表明 ,预聚体与 TPS之间发生了反应 ,为反应性涂层 ;样品表面的接触角变化速率由原来的 3 .90°/ min变为 0 .3～ 0 .4°/ min,表明 TDI/蓖麻油体系涂层样品表面的疏水性能与 TPS相比有了很大的改善。涂层液的粘度及 n(— NCO) / n(— OH)比例对材料厚度等性能有很大的影响 ,n(—NCO) / n(— OH)为 2时 ,涂层表面光滑透明 ,韧性好 ,具有良好的综合性能 ;n(— NCO) / n(— OH)大于 2时 ,涂层表面粗糙且脆。涂层厚度可以通过改变涂层预聚体的粘度来进行调节。     

粗糙PTFE涂层表面结构对乙醇/水混合溶液润湿性的影响

以具有粗糙结构的超疏水的聚四氟乙烯(PTFE)涂层为基体, 研究具有不同表面张力的乙醇/水混合溶液在表面的润湿. 通过空气分率的计算并进行液滴受力分析. 结果表明, 随着表面张力的降低, 乙醇/水混合溶液逐渐填满涂层表面的粗糙结构, 当表面张力大于约28 mN·m-1时, 溶液首先填满表面上的条纹状结构; 当表面张力小于约28 mN·m-1时, 溶液填满表面上的乳突状结构. 当条纹状结构被填满时, 粗糙表面空气分率下降很小, 溶液不能润湿PTFE涂层表面;当乳突状结构被填满时, 粗糙表面空气分率迅速下降,溶液能够润湿PTFE涂层.     

LC4铝合金表面电泳沉积硅锆有机-无机杂化涂层的制备及性能

采用阴极电泳沉积的方法在LC4铝合金表面制备硅锆有机-无机杂化涂层, 并探讨了电泳沉积条件对涂层形貌、结构以及耐蚀性的影响. 采用纳米粒度仪检测了不同硅锆杂化溶胶的zeta电位; 采用扫描电子显微镜(SEM)和原子力显微镜(AFM)观察了涂层的表面微观形貌和粗糙程度; 采用傅里叶红外光谱(FTIR)研究了涂层的化学结构; 采用电化学方法研究了沉积电压对涂层耐蚀性能的影响, 进而探讨了电泳沉积增强杂化涂层耐蚀性的机理. 结果显示沉积体系的pH为1.6、沉积电压为5 V时为最佳的沉积条件, 所获得的硅锆有机-无机杂化涂层表面均匀致密性最好, 粗糙程度和耐蚀性都得到了明显的改善, 在3.5% NaCl溶液中体现出较好的耐蚀作用.     

聚醚醚酮复合材料表面生物活性涂层的制备与性能

以聚醚醚酮/钡玻璃粉(PEEK-BGF)复合材料为基体, 通过硅烷偶联剂, 在复合材料表面构建具有生物活性的纳米羟基磷灰石(nHA)和甲基丙烯酸酯基的光固化树脂复合涂层. 采用扫描电子显微镜(SEM)和X射线光电子能谱(XPS)分析了材料表面形貌和元素分布, 测试了涂层与复合材料之间的粘接强度. 通过检测大鼠成骨细胞总蛋白含量和碱性磷酸酶表达水平, 评价新型光固化纳米羟基磷灰石/聚甲基丙烯酸酯(nHA/PMMA)复合涂层的生物活性. 研究结果表明, nHA填充的光固化复合材料形成粗糙的表面, 随着nHA的填充量提高, 涂层表面生物学活性得到提高.     

TiO_2-K_2SiO_3无机涂层对空间材料Ag的防护行为研究

在微波电离型原子氧 (AO)源地面模拟设备中对空间材料Ag及TiO2 K2 SiO3 无机涂层进行原子氧剥蚀效应试验 .用扫描电镜 (SEM)、光电子能谱 (XPS)、红外光谱 (FT IR)、X射线衍射光谱 (XRD)和LAMBDA 9分光光度计 ,对在模拟原子氧(AO)环境中Ag及在其表面涂覆的无机涂层 ,所发生的侵蚀与防护作用进行了表征研究 .AO对Ag表现了较严重的侵蚀作用 ,原来光亮如镜的表面形貌变得粗糙 ,且失去光泽 .而所施用的TiO2 K2 SiO3 无机涂层 ,经AO辐照后 ,表面形貌则变化甚少 .实验表明 ,该涂层对AO辐照有较强的防护效果、较好的空间稳定性 (AO辐照前后Δαs≈ 0 .0 2 4) ,能阻止AO对基材的侵蚀 .     

铝合金表面超疏水涂层的制备及其耐蚀性能

基于含氟聚氨酯和纳米SiO₂的协同作用, 在铝合金表面成功制备了一层超疏水涂层. 用红外光谱、扫描电镜和电化学测试等技术对超疏水涂层进行了表征和分析. 红外光谱结果表明, 硅烷偶联剂(A1100)成功键合到纳米SiO₂表面. 扫描电镜和接触角测定仪对涂层的表面形貌表征结果表明, 涂层表面存在微米鄄亚微米尺度的粗糙结构, 接触角可达到156°, 滚动角小于5°. 电化学测试(交流阻抗和极化曲线)结果表明, 所得到的涂层极大地提高了铝合金的耐蚀性能.     

羟基磷灰石/氧化铁复合涂层的制备及其诱导骨生长的生物活性

用电泳沉积法制得羟基磷灰石/壳聚糖/氧化铁(HA/CS/Fe2O3)复合涂层,经700 ℃烧结处理得到HA/Fe2O3复合涂层。 通过SEM、EDS、XRD、FT-IR、电化学和万能材料试验机等对复合涂层的表面形貌、物相组成、抗腐蚀性和结合强度进行了表征和测试,最后采用1.5SBF浸泡法对复合涂层的生物活性进行了评价。 结果表明,当悬浮液中的HA、CS与Fe2O3质量比为100∶100∶1时,所制得的HA/Fe2O3复合涂层表面粗糙,抗腐蚀性强,具有良好的诱导骨生长生物活性,基体与复合涂层结合强度可达27.5 MPa。     

环氧树脂/硅基-纳米SiO_2涂层的制备及防腐蚀性能

采用硅氢加成反应制备了2-(3,4-环氧环己基)乙基三乙氧基硅烷(ETEO),用ETEO对纳米SiO_2进行表面接枝得到新型硅基纳米SiO_2(ETEO-SiO_2),并制备环氧树脂/ETEO-SiO_2复合涂层.利用傅里叶变换红外光谱(FTIR)、氢核磁共振谱(~1H NMR)与X射线光电子能谱分析(XPS)对ETEO和ETEO-SiO_2进行了表征.场发射扫描电子显微镜(FESEM)观察到ETEO-SiO_2涂层横截面粗糙,ETEO-SiO_2具有良好分散性.接触角分析表明ETEO-SiO_2涂层疏水性提高.利用电化学阻抗实验与盐雾实验研究了复合涂层的防腐蚀性能,结果表明,添加ETEO-SiO_2纳米粒子后涂层的防腐蚀性能远优于纯环氧树脂和纳米SiO_2复合环氧树脂涂层,当ETEO-SiO_2纳米粒子添加量达到4%(质量分数)时,防腐蚀性能最佳.纳米SiO_2表面接枝ETEO后,ETEOSiO_2纳米粒子与环氧树脂基体之间的相容性增加,分散稳定性提高,涂层更加致密,减少了腐蚀介质所需的扩散通道并抑制腐蚀反应过程的进行,提高了复合涂层的防腐蚀性能.     

光导薄膜表面静电荷积累过程的动力学特征

本文对电照相用高分子光导材料薄膜涂层的表面电性能进行了研究,确定了表面充电过程宏观动力学的表征方法、动力学方程以及影响电荷沉积速度的因素。     

超疏水涂层表面粗糙结构对防覆冰性能的影响

结冰给交通、电力输送和航空等领域带来极大的安全隐患,研究防覆冰技术具有重要的应用价值。目前最具前景的防冰方法是涂层防冰,本文介绍了疏水涂层的构建方法,阐述了涂层疏水性和疏冰性之间的关系;重点论证了涂层表面粗糙结构对其防覆冰性能的影响,指出防覆冰涂层研发中存在的问题,并对该领域的发展趋势进行了分析和展望。     

Hydrophobicity and freezing of a water droplet on fluoroalkylsilane coatings with different roughnesses

Smooth (Ra approximately 0.1 nm) and rough (Ra approximately 20 nm) coatings of 1H,1H,2H,2H-perfluorodecyltrimethoxysilane (FAS-17) were prepared by controlling process conditions. The water contact angles for the smooth and rough coatings were similar (107 degrees and 110 degrees, respectively), but their sliding angles differed considerably (10 degrees and 27 degrees, respectively). The surface potential on the smooth coating, assessed using Kelvin force microscopy, showed a sharp distribution, but that on the rough coating ranged widely, implying large chemical heterogeneity including residual SiOH groups. The freezing temperature of a supercooled water droplet on the rough coating was higher than that on the smooth coating.     

喷涂法制备功能性超疏水复合涂层及其性能研究

以常用工程材料硅树脂BP与St(o)ber法合成的二氧化硅(SiO2)分散液为原料,运用喷涂法(spray-coating)制备出了功能性微/纳粗糙(MNR)结构的超疏水涂层,其接触角可以达到146.5°,滚动角小于1°(测试液滴量为15μL).通过分析喷涂法制备复合涂层所需的条件,得出喷涂液pH＝7.7-8.0时,在...     

Preparation and characterization of a new sol–gel hybrid based tetraethoxysilane-polydimethylsiloxane as a stir bar extraction sorbent materials

A new tetraethoxysilane-polydimethylsiloxane (TEOS-PDMS) for use as sorbent of stir bar sorptive extraction (SBSE) towards two selected organophosphorus pesticides (OPPs) namely chlorpyrifos and malathion was successfully synthesized through sol–gel technology. Four different molar ratios of TEOS:PDMS (1:1, 2:1, 3:1 and 4:1) sol solutions were prepared and dipped coated onto the surface of a glass-encased stir bar. Extraction efficiency of the prepared coatings towards the two selected OPPs were compared. A number of factors have been found to greatly affect the characteristics and properties of a particular sol–gel coating. Hence, in this study, several sol–gel coating conditions have been optimized using the optimized molar ratio 3:1 TEOS:PDMS to obtain the best coating as the stationary phase for SBSE. The raw OH-TPDMS and TEOS were characterized using Fourier Transform Infrared Spectroscopy (FT-IR) and compared with spectra of the four different molar ratios of TEOS:PDMS. The FT-IR spectrum of TEOS:PDMS showed the co-polymerization between PDMS and hydrolyzed TEOS molecules demonstrating the formation of the hybrid network in the sol–gel hybrid material. Surface morphology of hybrid sol–gel TEOS-PDMS with optimized molar ratio of 3:1 TEOS:PDMS were examined using FE-SEM. The surface of the sol–gel coating seems to be rough and homogeneous. The more rough structure formed by the 3:1 molar ratio TEOS:PDMS provides enhanced surface area which in turn improved sample capacity or adsorption process.     

AFM characterization of dendrimer-stabilized platinum nanoparticles

This work describes the use of atomic force microscopy (AFM) to measure the size of dendrimer-stabilized Pt nanoparticles (Pt DNs) deposited from aqueous solutions onto mica surfaces. Despite considerable previous work in this area, we do not fully understand the mechanisms by which PAMAM dendrimers template the formation of Pt DNs. In particular, Pt DN sizes measured by high-resolution transmission electron microscopy (HRTEM) are reported to be larger than expected if one assumes that each PAMAM molecule templates one spherical Pt nanoparticle. AFM provides a vertical height measurement that complements the lateral dimension measurement from HRTEM. We show that AFM height measurements can distinguish between "empty" PAMAM and Pt DNs. If the complexation of Pt precursor with PAMAM is prematurely terminated, AFM images and feature height distributions show evidence of arrested precipitation of Pt colloids. In contrast, sufficient Pt-PAMAM complexation time leads to AFM images and height distributions that have relatively narrow, normal distributions with mean values that increase with the nominal Pt:PAMAM ratio. The surface density of features in AFM images suggest that these Pt DNs reside on the mica surface as two-dimensional surface aggregates. These observations are consistent with an intradendrimer templating mechanism for Pt DNs. However, we cannot determine if the mechanism obeys a fixed loading law because we do not have definitive information about Pt DN shape. A second peak in the Pt DN height distribution appears when the Pt loading exceeds about 66% of PAMAM's theoretical capacity for Pt. Excluding these secondary particles, the dependence of mean feature height on the Pt:PAMAM ratio follows a power-law relationship. Also considering the magnitudes of the measured mean height values, the data suggest that Pt DNs exist as ramified, noncompact aggregates of Pt atoms interspersed within the PAMAM framework.     

Synthesis of novel hybrid films of a layered silicate and alkylammonium cations on rough polymeric surfaces by Langmuir–Blodgett method

Hybrid films of a layered silicate and an amphiphilic alkylammonium (hexadecyltrimethylammonium) cation have been prepared by Langmuir–Blodgett (LB) method and transferred onto a polyamide surface by dip coating. This is the first time that stable LB hybrid monolayer and multilayer films have been formed on rough polymeric surfaces. The films were characterized by X-ray diffraction (XRD), fourier transform infrared spectroscopy (FTIR), atomic force microscopy (AFM) and water contact angle measurements. XRD and FTIR showed that the hybrid multilayer was well-organized and the thickness of one layer was calculated to be 1.6 nm. Furthermore, the layered silicate was determined to be on the substrate side and the amphiphilic molecule layer was exposed to the air side. This provides a novel methodology for the surface modification of polymers.     

Wettability conversion from superoleophobic to superhydrophilic on titania/single-walled carbon nanotube composite coatings

Superoleophobic surfaces were demonstrated on perfluorosilane-rendered titania (TiO(2))/single-walled carbon nanotube (SWNT) composite coatings. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) observations revealed that SWNTs play a key role in the formation of overhanging structures and the nanoscale roughness on the coating surface, which compose the two critical morphologic factors for a superoleophobic surface. The wettability conversion from superoleophobic to superhydrophilic of the composite coatings was realized by the gradual decomposition of 1H,1H,2H,2H-perfluorodecyltrichlorosilane (FDTS) on the coating surface using UV irradiation. Contact angle measurement on both smooth TiO(2) surface and rough composite coating surface under different UV irradiation time revealed that the wetting behavior of the liquids on the composite coating surface passes from the Cassie to the Wenzel and finally to the inversed-Cassie regime. Different liquids show different irradiation time for the wetting state change. By controlling the UV irradiation dose, liquids with surface tension difference smaller than 5 mN/m can exist in completely converse wetting states on the same coating surface, that is, superphobic for one liquid while superphilic for another with lower surface tension. Mixed organic liquids with different surface tension can be completely separated through a coated grid using this wettability tuning technique.     

Surface Properties of Graphene Functionalized TiO2/nHA Hybrid Coatings Made on Ti6Al7Nb Alloys via Plasma Electrolytic Oxidation (PEO)

Nano-hydroxyapatite (nHA)-matrix coatings containing graphene nanosheets (GNS)-nHA were coated on Ti6Al7Nb alloys by plasma electrolytic oxidation (PEO) treatment for the improvement of their surface properties. Crystallographic properties, functional groups, and elemental analysis of coatings were characterized by XRD, ATR–FTIR, and EDS analysis. Surface morphological changes of the coated surfaces were investigated by AFM and SEM. The electrochemical corrosion behavior of the coatings was examined by using the potentiodynamic scanning (PDS) tests under in-vitro conditions in simulated body fluid (SBF). The results showed that the GNS was successfully deposited in ceramic matrix coatings on Ti6Al7Nb alloys. Also, the microstructural observations revealed that the coatings have a porous and rough structure. The XRD and ATR–FTIR quantitative analysis have proved the appearance of HA and GNS in the coating layers. An increase in the coating thickness, surface hardness, and anatase/rutile transformation rate was determined, while the GNS ratio in the coating layers was increased. The microhardness of the nHA coating reinforced with 1.5 wt% GNS was measured at 862 HV, which was significantly higher than that of GNS-free (only nHA) coating (584 HV). The best in-vitro resistance to corrosion in SBF was observed in the nHA/1.5GNS wt% coating.     

绿色合成氧化铈构建导尿管抗菌水凝胶涂层

因导尿管引起的微生物感染严重危害患者健康,并容易导致细菌耐药性。基于纳米材料的抗菌涂层是应对导尿管感染的最有效策略之一。本文利用绿色小球藻自身及其分泌物的还原性环境,制备合成高表面活性的纳米氧化铈Bio-CeO₂,能够高效产生活性氧自由基,实现对大肠杆菌、铜绿假单胞菌等致病菌的抑制和杀伤。在这种绿色合成的模拟酶纳米材料基础上,将其与壳聚糖、京尼平等生物基材料协同作用,在导尿管表面构建稳定的抑菌水凝胶涂层。结果显示,包覆有Bio-CeO₂水凝胶抗菌涂层的硅胶导尿管比裸导管的抑菌效果显著增强,尤其是在低浓度的过氧化氢溶液环境下,对铜绿假单胞菌的抑菌效率可提升至54%,这为未来新型广谱抗菌导尿管的设计和感染性疾病的预防控制提供了潜在新材料和技术手段。