液相沉积法制备光催化活性TiO2薄膜和纳米粉体

采用液相沉积法 ,在 3 5℃通过向六氟钛酸铵水溶液中添加硼酸和结晶诱导剂锐钛矿型TiO2 纳米晶 ,沉积出具有光催化活性的TiO2 薄膜和纳米粉体 .用XRD ,AFM ,阶梯仪 ,UV vis ,BET法对TiO2 薄膜和粉体的沉积条件、结构、厚度和性能进行了测定和表征 ,并用亚甲兰的降解 ,评价了TiO2 薄膜和纳米粉体的光催化活性 .结果表明 ,当反应物六氟钛酸铵与硼酸的摩尔比为 1∶2～ 1∶4时 ,沉积的粉体和薄膜含有锐钛矿相TiO2 ;经 3 0 0℃热处理的TiO2 薄膜和纳米粉体具有最高的光催化活性 ,它的光催化活性是未经热处理前的 5倍 .本文还解释了经 3 0 0℃热处理的薄膜和纳米粉体具有最高光催化活性的原因     

液相沉积法制备光催化活性TiO2膜

锐钛矿型TiO2薄膜;液相沉积法制备光催化活性TiO2膜     

微波辅助液相沉积法快速制备纳米氧化钛晶体

Anatase nanoparticles were successfully prepared via a facile microwave assisted liquid phase deposition （MW-LPD） process with hexafluorotitanate ammonium （NH4）2TiF6 as precursor. Compared with the conventional LPD processes, the MW-LPD technique could provide high yield quickly and crystallinity in a diluted precursor solution at a low temperature. The products were characterized by XRD and TEM. Their photocatalytic activities were also investigated by the photodegradation of methylene blue （MB） as a model molecule.     

液相沉积法制备光催化活性TiO2薄膜和纳米粉体

采用液相沉积法，在35℃通过向六氟钛酸铵水溶液中添加硼酸和结晶诱导剂锐 铁矿型TiO2纳米晶，沉积出具有光催化活性的Ti02薄膜和纳米粉体．用XRD，AFM， 阶梯仪,UV-vis，BET法对Ti02薄膜和粉体的沉积条件、结构、厚度和性能进行了测 定和表征，并用亚甲兰的降解，评价了TiO2薄膜和纳米粉体的光催化活性．结果表 明，当反应物六氟钛酸铵与硼酸的摩尔比为1：2—1：4时，沉积的粉体和薄膜含有 锐钛矿相Ti02；经300℃热处理的Ti02薄膜和纳米粉体具有最高的光催化活性，它 的光催化活性是未经热处理前的5倍．本文还解释了经300℃热处理的薄膜和纳米粉 体具有最高光催化活性的原因．     

超亲水TiO2和TiO2-SiO2表面的动态润湿性

1997年, Fujishima研究组[1]发现TiO2表面经UV光照射能产生较强的亲水性, 同时具有较高的亲油性, 即经UV光照射后的TiO2表面具有超双亲的性质. 这种防雾和自清洁性在工业上应用广泛, 已引起了人们的极大兴趣[2～5]. 进一步的研究发现, 超亲水的TiO2表面在暗处放置会变为疏水表面. 对于这个问题, 除了可以通过UV光照[6]、氩离子或电子束溅射[6]和高温热处理[5]等恢复其超亲水性外, 还可以通过添加摩尔分数为10%～30%的SiO2有效地降低TiO2表面的接触角, 提高UV光诱导的超亲水表面在暗处的稳定性能[3]. 另外, 诱导TiO2的亲水性需要较强的UV线强度(如太阳光), 使它在室内应用受到限制. 为了在室内实现TiO2的自清洁功能, Watanabe等[4]发现在TiO2中添加WO3可使TiO2在室内的照明光下也能实现亲水性转变. 以上这些研究成果为TiO2在工业和生活上的实际应用提供了重要的科学依据. 然而, TiO2的防雾和自清洁功能的实现同时也受其动力学性质的制约.     

聚多巴胺辅助的液相沉积法制备二氧化钛涂层毛细管柱及其在电色谱中的应用

利用多巴胺的自氧化聚合反应在毛细管内壁引入聚多巴胺涂层,并以聚多巴胺涂层作为连接臂辅助二氧化钛前躯体氟钛酸铵液相沉积制备了二氧化钛涂层毛细管柱。该方法制备过程简单,条件温和,形成的涂层稳固。采用X射线光电子能谱(XPS)、扫描电镜(SEM)和测定电渗流变化对涂层性质进行了表征。选择5种阴离子、生物碱作为分离对象,考察了缓冲液组成、浓度和p H值等因素对该涂层柱毛细管电色谱分离性能的影响。结果显示,在优化条件下,5种阴离子及生物碱在该涂层毛细管柱上均能得到较好的分离。     

High-Quality Thin Films of UiO-66-NH2 by Coordination Modulated Layer-by-Layer Liquid Phase Epitaxy

We report the fabrication of macroscopically and microscopically homogeneous, crack-free metal-organic framework (MOF) UiO-66-NH₂ (UiO: Universitetet i Oslo; [Zr₆O₄(OH)₄(bdc-NH₂)₆]; bdc-NH₂²⁻: 2-amino-1,4-benzene dicarboxylate) thin films on silicon oxide surfaces. A DMF-free, low-temperature coordination modulated (CM), layer-by-layer liquid phase epitaxy (LPE) using the controlled secondary building block approach (CSA). Efficient substrate activation was determined as a key factor to obtain dense and smooth coatings by comparing UiO-66-NH₂ thin films grown on ozone and piranha acid-activated substrates. Films of 2.60 μm thickness with a minimal surface roughness of 2 nm and a high sorption capacity of 3.53 mmol g⁻¹ MeOH (at 25 °C) were typically obtained in an 80-cycle experiment at mild conditions (70 °C, ambient pressure).     

Photosensitization of TiO2 nanoparticulate thin film electrodes by CdS nanoparticles

Surface photovoltage spectra (SPS) measurements of TiO₂ show that a large surface state density is present on the TiO₂ nanoparticles and these surface states can be efficiently decreased by sensitization using CdS nanoparticles as well as by suitable heat treatment. The photoelectrochemical behavior of the bare TiO₂ thin film indicates that the mechanism of photoelectron transport is controlled by the trapping/detrapping properties of surface states within the thin films. The slow photocurrent response upon the illumination can be explained by the trap saturation effect. For a TiO₂ nanoparticulate thin film sensitized using CdS nanoparticles, the slow photocurrent response disappears and the steady-state photocurrent increases drastically, which suggests that photosensitization can decrease the effect of surface states on photocurrent response. Electronic Publication     

Tribological properties of multilayer nanostructure TiO2 thin film doped by SiO2

Multilayer of TiO₂ and TiO₂:SiO₂ thin films were grown on a glass substrate by sol?Cgel processes, followed by high temperature treatment at 500?°C. The fine grained TiO₂ films controlled by SiO₂ dopant showed very good wear resistance and endurance life. Energy dispersive X-ray spectroscopy was used to indicate the elements in the films. X-ray diffraction analyses indicated that TiO₂ and TiO₂:SiO₂ film contain only anatase phase. The morphologies of the original and worn surfaces of the samples were analyzed by means of scanning tunneling microscope and scanning electron microscopy. The tribological properties of TiO₂ and TiO₂:SiO₂ thin films sliding against AISI52100 steel pin were evaluated on a pin on disk friction and wear tester. The results showed that 25-layer TiO₂:SiO₂ films are superior in reducing friction and resisting wear compared with the glass substrate.     

Anomalous lithium ion diffusion into CeO2·TiO2 thin film by film thickness variations

CeO₂·TiO₂ thin film is considered as an excellent candidate for a passive ion storage layer due to its good electrochemical stability and comparatively great charge capacitance. When cerium-titanium oxide thin film is adopted as an ion storage layer against cathodic tungsten oxide layer, the electrochromic device shows long term durability and cyclability. Therefore, many researchers investigated the composition and crystallinity effects to the charge density. In our study, we prepared CeO₂·TiO₂ thin by sol–gel dip-coating method, varying thickness by controlling withdrawal speeds. As investigating results of cyclic voltammetry and chronocoulometry, we found that there are three regions in the film thicknesses: (1) fast lithium ion diffusion region under 100 nm, (2) slow diffusion region in the range of 100 to 150 nm, and (3) fast and great charge capacitance region over 150 nm. In region 1, lithium ions diffuse very fast and reach into indium-tin oxide (ITO) layers, and slow diffusion region follows in region 2, probably due to the remains or impurities within the film, and in region 3, lithium ion diffusion gets fast again, accompanied with charge capacitance increase with thickness.     

Chemical surface modification of poly(p-xylylene) thin films

Electrophilic aromatic substitution reactions were studied at poly(p-xylylene) (PPX) film surface-reaction medium interfaces. The extent of the reactions (depth of penetration and degree of substitution) was determined by the interaction of the polymer with the reaction solution. Reaction with chlorosulfonic acid to produce sulfonyl chloride and sulfone functionalities occurred readily in the bulk of PPX, and yields were sensitive to time and temperature. Confinement of this reaction to the PPX surface was achieved by controlling the concentration of the acid. Functionalization of PPX with N-methylol-2-chloroacetamide in sulfuric acid to produce the chloroamidomethylated derivative occurred in high yield and was confined to the surface region of PPX. Hydrolysis of the amide to generate aminomethylated PPX was assessed by XPS and a derivatization reaction. Friedel-Crafts type chemistry (acylation and alkylation reactions) also produced functionalized surfaces, but with lower degrees of substitution than the other two reactions and was strictly surface-confined.     

二氧化钛纳米材料的非均相光催化本质及表面改性

非均相光催化过程是指多相多尺度体系在光辐射作用下发生的一个复杂的催化过程,被认为最有潜力解决环境污染和能源短缺问题的绿色及可再生的技术之一。在目前已经报道的各种非均相光催化剂中, TiO2纳米材料被证实是应用最广泛、光催化效果最好的催化剂,是当前国际材料、环境和能源等领域的研究前沿和热点,高性能TiO2基光催化材料的设计及改性一直是该领域的难点,其关键问题主要为：如何增强TiO2的表面光催化量子效率、促进光生载流子分离和拓展其可见光响应范围。尽管已经有很多关于TiO2光催化的综述,但大多综述集中在高性能TiO2的制备及各种改性策略研究,而对各种改性策略与光催化分子机理之间的关系阐述较少。为此,本文深入分析了TiO2纳米材料的非均相光催化本质并总结了各种表面改性策略。首先从热力学角度阐明TiO2的热力学能带能够确保其实现各种典型光催化反应(包括光催化降解、CO2还原及光解水),证实其广泛应用的可行性。然后,对TiO2光生载流子的动力学基础进行总结,证实快速的广生载流子复合以及较慢的表面化学反应动力学是限制其光催化活性提高的关键制约性因素。于此同时,对TiO2纳米材料的表面Zeta点位、超亲水性、超强酸光催化剂制备(表面羟基取代)等重要的表面化学性质也进行了详细阐述。从而可以初步得出如下结论：表面改性是设计高性能TiO2光催化材料的重中之重,并将各种改性策略浓缩在6个方面：表面掺杂和敏化,构建表面异质结,负载纳米助催化剂,增加可利用的比表面剂,利用表面氟效应以及暴露高活性晶面等。显然,表面掺杂和敏化可以减小TiO2纳米材料的禁带宽度,从而大幅拓宽其可见光吸收范围及光催化效率。而构建紧密的表面异质结可以创建界面电场,不仅可以促进光生电荷分离效率,而且可以有效提高界面电荷转移效率,最终实现异质结的高光催化效率。负载纳米助催化剂则可以大幅加快表面化学反速率,降低光生载流子的表面复合并增加其利用率,并有可能减少不期望的表面逆反应,从而实现光催化活性提升。增加可利用的比表面剂,可以有效提升光催化剂与吸附质之间的有效接触面积,缩短了载流子的传输距离以及通过多次反射与折射提升光能的利用率,从而全方位地提升TiO2纳米材料的光催化活性。对TiO2纳米材料表面进行氟化,可以增加光生羟基自由基的速率以及浓度,并可以通过调节TiO2表面酸碱性而控制其光催化选择性,从而实现高效高选择性光催化。最后,通过暴露TiO2纳米材料的高活性晶面,也可以促进光生载流子分离、增加吸附性能或羟基自由基生成速率,从而获得高光催化效率。另外,这些表面改性策略的协同效应仍是较有前景的TiO2纳米光催化剂改性技术,值得深入研究。同时,深入的光催化分子机理探索仍然是必须的,其不仅有助于发现影响TiO2纳米材料光催化活性提高的关键性制约因素,而且也可以指导开发新型的TiO2纳米光催化剂改性技术。总而言之,通过总结TiO2纳米材料在光催化、表面化学及表面改性等方面的重要进展,可为设计高效的TiO2基及非TiO2基光催化剂并应用于太阳燃料生产、环境修复、有机合成及相关的领域(如太阳能电池、热催、分离和纯化)等提供新的思路。     

Activation of surface hydroxyl groups by modification of H-terminated Si(111) surfaces

Chemical functionalization of semiconductor surfaces, particularly silicon oxide, has enabled many technologically important applications (e.g., sensing, photovoltaics, and catalysis). For such processes, hydroxyl groups terminating the oxide surface constitute the primary reaction sites. However, their reactivity is often poor, hindering technologically important processes, such as surface phosphonation requiring a lengthy postprocessing annealing step at 140 °C with poor control of the bonding geometry. Using a novel oxide-free surface featuring a well-defined nanopatterned OH coverage, we demonstrate that hydroxyl groups on oxide-free silicon are more reactive than on silicon oxide. On this model surface, we show that a perfectly ordered layer of monodentate phosphonic acid molecules is chemically grafted at room temperature, and explain why it remains completely stable in aqueous environments, in contrast to phosphonates grafted on silicon oxides. This fundamental understanding of chemical activity and surface stability suggests new directions to functionalize silicon for sensors, photovoltaic devices, and nanoelectronics.     

Highly efficient dye-sensitized solar cells by TiCl4 surface modification of ZnO nano-flower thin film

Journal of Solid State Electrochemistry - In dye-sensitized solar cells (DSSCs), the semiconductor photo-anode film plays a significant role in enhancing the overall power conversion efficiency....     

Fabrication,Characterization and Optical Properties of TiO2 Nanotube Arrays on Boron-doped Diamond Film Through Liquid Phase Deposition

TiO2 nanotube（TiNT） arrays were deposited on boron-doped diamond films by a liquid-phase deposition method with ZnO nanorod arrays as the template.The different morphologies of TiNTs have been obtained by controlling the morphology of ZnO template.The X-ray diffraction and energy-dispersive X-ray analysis show that the ZnO nanorod array template has been removed in the TiNTs formation process.The crystalline quality of the TiNTs is improved by increasing the annealing temperature.The band gap of the TiNTs is about 3.25 eV estimated by the UV-Vis absorption spectroscopy,which is close to the value of bulk TiO2.In the photoluminescence spectrum,a broad visible emission in a range of ca.550-750 nm appears due to the surface oxygen vacancies and defects.     

Adsorption and desorption of toluene on nanoporous TiO2/SiO2 prepared by atomic layer deposition (ALD): influence of TiO2 thin film thickness and humidity

Adsorption and desorption of toluene on bare and TiO₂-coated silica with a mean pore size of 15 nm under dry and humid conditions were studied using toluene breakthrough curves and temperature programmed desorption (TPD) of toluene and CO₂. Two TiO₂/silica samples (either partially or fully covered with TiO₂) were prepared with 50 and 200 cycles of TiO₂ atomic layer deposition (ALD), respectively. The capacity of silica to adsorb toluene improved significantly with TiO₂-thin film coating under dry conditions. However, toluene desorption from the surface due to displacement by water was more pronounced for TiO₂-coated samples than bare samples under humid conditions. In TPD experiments, silica with a thinner TiO₂ film (50-ALD cycled) had the highest reactivity for toluene oxidation to CO₂ both in the absence and presence of water. Toluene adsorption and oxidation reactivity of silica can be controlled by modifying the silica surface with small amount of TiO₂ using ALD.     

Coupling of carbon monoxide molecules over oxygen-defected UO2(111) single crystal and thin film surfaces

While coupling reactions of carbon-containing compounds are numerous in organometallic chemistry, they are very rare on well-defined solid surfaces. In this work we show that the reductive coupling of two molecules of carbon monoxide to C2 compounds (acetylene and ethylene) could be achieved on oxygen-defected UO2(111) single crystal and thin film surfaces. This result allows in situ electron spectroscopic investigation of a typical organometallic reaction such as carbon coupling and extends it to heterogeneous catalysis and solids. By using high-resolution photoelectron spectroscopy (HRXPS) it was possible to track the changes in surface states of the U and O atoms as well as identify the intermediate of the reaction. Upon CO adsorption U cations in low oxidation states are oxidized to U4+ ions; this was accompanied by an increase of the O-to-U surface ratios. The HRXPS C 1s lines show the presence of adsorbed species assigned to diolate species (-OCH=CHO-) that are most likely the reaction intermediate in the coupling of two CO molecules to acetylene and ethylene.     

Adsorption and assembly of copper phthalocyanine on cross-linked TiO2(110)-(1 x 2) and TiO2(210)

Copper phthalocyanine (CuPc) on reconstructed rutile TiO(2) was studied with ultrahigh vacuum variable temperature scanning tunneling microscopy. On cross-linked TiO(2)(110)-(1 x 2), the CuPc molecules at low coverages sparsely lay flat at the link sites and tilted in troughs between [001] rows. Increase of the CuPc coverage led to the trapping of the CuPc molecules by the rectangular surface cells fenced by the oxygen columns along the [001] direction and the cross-link rows. Each cell could trap one CuPc molecule at intermediate coverages and two CuPc molecules at higher coverages. On TiO(2)(210), the CuPc molecules tilted in defect-free areas and lay at defect sites with their molecular planes parallel to the substrate surface. Further increase of the CuPc coverage induced the formation of one- and two-dimensional assemblies on TiO(2)(210).     

低温液相制备金红石型TiO2纳米晶须

目前，已有多种控制TiO2形貌及晶须生长的方法，如模板合成、超分子组装、声化学合成液相法及固相合成等，其中，液相法是最为廉价和简单的方法．为此，近期采用低温液相法合成金红石型TiO2受到了极大的关注．本文在以前工作的基础上，采用改进的实验方法通过在低温陈化一定浓度的TiCl4水溶液直接获得了金红石型TiO2纳米晶须，并对产物进行了初步表征．     

Molecular dynamics simulation of surface segregation in a (110) B2-NiAl thin film

Surface segregation in (110) B2-NiAl film approximately 3 nm thick is investigated by using molecular dynamics simulation with a reliable embedded-atom potential. The simulation is performed for the stoichiometric composition at a temperature of 1500 K, just below the melting temperature of the film model. It is found that the (110) surface is structurally stable but develops adatoms, vacancies and antisites. The coverage of an adatom layer is estimated to be ～0.07 ML (monatomic layers) and it contains on average ～95% of Al atoms. The top (surface) and second (subsurface) layers of the (110) surface is the most enriched in Ni relative to the bulk composition. These layers contain on average ～51% of Ni atoms. The Ni fraction in the third and forth layers of the film is estimated as ～50.5%. The deeper layers have essentially the bulk composition. Vacancies in the film model are found only on the Ni sublattice. The vacancy concentration on the Ni sublattice in the top layer is ～7.5%. The second layer almost does not contain vacancies. The next layers have essentially the constant bulk vacancy composition which can be estimated as ～1.3-1.4%.