镓酸镧基中温-SOFC的新型阳极NiO-La0.3Ce0.7O2-δ研究

采用共沉淀法制备了NiO-La0.3Ce0.7O2-δ(LDC30)新型阳极材料, 通过对其配方与性能的研究, 探索获得中温SOFC高性能阳极材料的新途径.     

以Fe2O3为原料制备LiFePO4/C复合材料及其性能研究

以Fe2O3为铁源原料, 利用热还原法成功地制备了LiFePO4/C复合材料. 用XRD以及SEM对材料的晶体结构以及表面形貌进行了表征. 通过循环伏安和充放电测试研究了材料的电化学性能. 研究结果表明， 于700 ℃下制备的LiFePO4/C复合材料在0.1C的倍率下可以得到放电容量144.8 mA·h/g, 在循环160次后, 容量仍保持在141.4 mA·h/g. 这种以廉价的Fe2O3代替目前常用的二价铁盐原料方法, 具有减少LiFePO4合成成本的优点.     

表面修饰DBS基团对TiO2气相光催化性能的影响

采用溶胶-水热法直接获得表面修饰十二烷基苯磺酸钠(DBS)分子基团的TiO2纳米粒子, 并考察了DBS表面修饰对纳米TiO2光催化氧化降解气相n-C5H12反应的活性和寿命的影响, 并利用表面光电压(SPS)谱和光致发光(PL)光谱等方法研究了DBS表面修饰的影响机制. 结果表明, 表面修饰DBS分子基团能够抑制TiO2纳米微晶生长, 促进纳米TiO2分散, 增强吸附性和提高光生电荷分离, 使光催化活性显著提高. 但寿命并未下降, 这与TiO2和DBS基团的光稳定性有关. 动力学研究结果表明, TiO2光催化氧化n-C5H12反应遵循Langmuir-Hinshelwood动力学模型, 为准一级反应.     

锂电池正极材料Li1.06Mn0.8Cr0.14O2的水热合成及其光谱研究

采用水热方法合成了掺铬锂锰氧化合物, X射线衍射和Raman光谱分析结果表明, 所得材料为具有NaFeO2结构的晶体. 由等离子发射光谱(CIP)确定其组分为Li1.06Mn0.8Cr0.14O2. X射线光电子能谱(XPS)研究结果表明, 与未掺杂的LiMnO2相比, 所得材料中Mn的平均价态增加, 这将抑制因Mn3+离子的存在而产生的Jahn-Teller畸变, 有利于提高材料的电化学循环性能.     

离子液体介质中用Cu/ZrO2-SiO2催化香茅醛加氢合成薄荷醇

制备了Cu/ZrO2-SiO2双载体催化剂, 并在离子液体介质中研究了香茅醛催化加氢合成薄荷醇的反应. 研究结果表明, 离子液体中的阳离子与香茅醛分子中的羰基形成氢键, 使香茅醛更容易异构化为胡异薄荷醇, 提高了催化剂的选择性; 特别是可调节酸度的[bmim][AlmCln]离子液体, 有效地提供了香茅醛的异构化所需要的路易斯酸条件, 在竞争性加氢中促进了香茅醛向生成薄荷醇的方向转化. 在0.8 MPa, 90 ℃, 2 h的条件下, 香茅醛一锅反应生成薄荷醇的转化率为100%, 对薄荷醇的选择性为91.3%, 而且, 催化剂和离子液体可回收和重复使用.     

BaCo0.7Fe0.2Nb0.1O3-δ膜反应器还原侧表面反应机理

研究了BaCo0.7Fe0.2Nb0.1O3-δ(BCFN)透氧膜反应器还原侧表面反应机理, 分析了表面催化微粒及催化床对膜反应器的作用. 提出了“催化解离机制”是构成甲烷重整BCFN膜反应器透氧量上升的主要原因; CH4, H2及CO在BCFN膜表面的反应活性依次为H2>CO>CH4; 当CH4气氛中加入H2或CO时, BCFN膜表面的主要发生由CH4直接氧化转变H2或CO的氧化反应, 同时极大提升了BCFN膜反应器的透氧量; BCFN膜表面氧化反应为“晶格氧”氧化反应模式主导.     

层状化合物La2Ni1-yCoyO4+δ的合成、结构与性能

采用氨基多羧酸配合物法合成La2Ni1-yCoyO4+δ(y=0~0.2)超细粉料, 研究陶瓷样品的结构和混合导电性能. 研究结果表明, La2Ni1-yCoyO4+δ具有正交结构(Fmmm空间群), Co离子取代增加了钙钛矿层中ab平面上Ni/Co—O键的键长、岩盐层中沿c 轴方向上La—O键的键长和非化学计量氧含量, 并有利于改善材料的烧结性能. 随着Co离子含量的增加, 总电导率的峰值温度向高温移动, 高温段总电导率随温度的变化趋于平缓, 但总电导率水平出现降低; 增加Co离子含量还有利于提高氧离子导电性能. Co离子取代对陶瓷样品混合导电性能的影响与晶体结构参数的变化紧密相关.     

金属富勒烯Y＠C36结构和性能的密度泛函研究

采用Cerius 2中的GGA/PW91密度泛函方法对具有D6h对称性的C36及其衍生物Y＠C36进行结构全优化, 系统地分析了Y在C36笼内不同占位时系统的能量及稳定性等, 并在同一方法下对结构全优化后的C36和Y＠C36进行了能量、能级、态密度及光学性能分析, 研究了Y原子的嵌入对C36结构和性能的影响.     

中温复合固体电解质SDC-LSGM的制备和性能

采用甘氨酸-硝酸盐法分别制备了Ce0.85Sm0.15O2-δ(SDC)与La0.9Sr0.1Ga0.8Mg0.2O3-δ(LSGM)两种电解质材料, 并用固相混合法将两种材料按不同质量比(SDC与LSGM的质量比分别为9∶1, 8∶2, 5∶5)混合制备复合电解质材料. 采用交流阻抗技术对样品的电学性能进行研究. 实验结果表明, SDC与LSGM的质量比为9∶1(SL91)时, 样品具有较高的电导率, 在350—800 ℃温度范围内其电导率均比SDC的高. 以复合电解质为支撑体, 以Sm0.5Sr0.5CoO3 为阴极、NiO/SDC 为阳极制成单电池, 测试结果显示, 在800 ℃时以SL91为电解质的单电池的最大输出功率密度为0.25 W/cm2, 最大电流密度为1.06 A/cm2. 在电池的工作温度区间(600—800 ℃)内以复合材料为电解质的单电池的开路电压比以SDC为电解质的高.     

单个Fe2O3@Au粒子的偏振表面增强拉曼光谱

本文首次报道了单个纺锤形Fe2O3@Au颗粒的偏振相关的SERS光谱, 为研究SERS机理提供了实验依据.     

阳极氧化法制备二氧化钛纳米管阵列的研究

采用电化学阳极氧化法,将纯钛浸入HF酸水溶液,在钛基体表面原位构建高度有序的二氧化钛纳米管阵列,探讨阳极氧化电压、电解液浓度和电解液温度等对二氧化钛纳米管阵列尺寸和形貌的影响。通过SEM、XRD对二氧化钛纳米管阵列的结构特征进行表征,结果表明,不同的阳极氧化电压、电解液浓度和温度都将影响TiO2纳米管阵列的尺寸和形貌,在阳极氧化电压为20V,HF电解液浓度为0.5%t条件下,可制备出结构规整有序的TiO2纳米管阵列。     

脉冲电沉积法制备Pt-TiO2 纳米管电极及其电催化性能

采用阳极氧化法在高纯钛片上原位组装TiO2纳米管阵列, 然后用脉冲电沉积方法将Pt沉积到TiO2纳米管阵列上, 制备出Pt-TiO2纳米管电极. 利用XRD和SEM对所获电极的微观结构和形貌进行表征, 结果表明, Pt纳米颗粒以花簇状分散在TiO2纳米管上, 晶粒大小约为25.6 nm. 对甲醇的电催化性能的研究结果表明, 脉冲电沉积制得的Pt-TiO2纳米管电极比TiO2纳米管电极和纯Pt片电极具有更高的电催化活性, 是Pt电极的40多倍.     

TiO_2一维纳米材料及其纳米结构的合成

本文对合成TiO2一维纳米材料及其有序纳米阵列的阳极氧化法、模板法以及水热法进行了全面而系统的评述,着重介绍了它们的最新研究进展。阳极氧化法能制备牢固负载于基体上的TiO2纳米管阵列,这有助于构筑TiO2纳米结构及其在纳米器件上的应用;与多种制备技术如溶胶-凝胶工艺、电化学沉积以及原子层沉积等相结合,模板法可以合成出多种形貌的TiO2纳米材料如纳米管、纳米线和纳米棒,并且可以通过改变所用模板的微观尺寸来调控TiO2一维纳米材料及其有序阵列的微结构参数;水热合成法可以制备出直径小且比表面积大的TiO2纳米管粉末。从目前来看,该法还不能制备出牢固负载于基体上的有序纳米阵列。文章最后指出了TiO2一维纳米材料及其有序纳米阵列合成中存在的问题及今后发展方向。     

Robust S-doped TiO2@N,S-codoped carbon nanotube arrays as free-binder anodes for efficient sodium storage

Titanium dioxide(TiO_2) has been investigated broadly as a stable,safe,and cheap anode material for sodium-ion batteries in recent years.However,the poor electronic conductivity and inherent sluggish sodium ion diffusion hinder its practical applications.Herein,a self-template and in situ vulcanization strategy is developed to synthesize self-supported hybrid nanotube arrays composed of nitrogen/sulfur-codoped carbon coated sulfur-doped TiO_2 nanotubes(S-TiO_2@NS-C) starting from H_2 Ti_2 O_5-H_2 O nanoarrays.The S-TiO_2@NS-C composite with one-dimensional nano-sized subunits integrates several merits.Specifically,sulfur doping strongly improves the Na~+ storage ability of TiO_2@C-N nanotubes by narrowing the bandgap of original TiO_2.Originating from the nanoarrays structures built from hollow nanotubes,carbon layer and sulfur doping,the sluggish Na~+ insertion/extraction kinetics is effectively improved and the volume variation of the electrode material is significantly alleviated.As a result,the S-TiO_2@NS-C nanoarrays present efficient sodium storage properties.The greatly improved sodium storage performances of S-TiO_2@NS-C nanoarrays confirm the importance of rational engineering and synthesis of hollow array architectures with higher complexity.     

纳米TiO_2膜修饰电极异相电催化还原马来酸

通过电化学合成前驱体和溶胶-凝胶法在Ti表面修饰一层纳米TiO_2膜，SEM， XRD测试表明晶型为锐钛矿型，晶粒平均尺寸为25 nm。采用循环伏安法、循环方波 伏安法和电解合成法研究了纳米TiO_2膜电极在硫酸介质中的氧化还原行为以及对 马来酸（maleic acid）还原的电催化活性。结果表明，纳米TiO_2膜电极在阴极扫 描时有两对可逆氧化还原峰，可逆半波电位E_(1/2)~r分别为-0.53 V和-0.92 V（ sv. SCE，扫描速度0.05 V·s~(-1)），对应于TiO_2/Ti_2O_3和TiO_2/Ti(OH)_3两 个氧化还原电对的可逆电极过程。其中TiO_2/Ti_2O_3电对对马来酸具有异相电催 化还原活性，纳米TiO_2膜中的Ti~(IV)/Ti~(III)氧化还原电对作为媒质间接电还 原马来酸为丁二酸（butane diacid），反应机理为电化学偶联随后化学催化反应 （EC'）机理。     

乙醇在碳修饰的二氧化钛纳米管负载的钯电催化剂上的催化氧化

 通过有机物分解碳化处理TiO2 纳米管制得了TiO2C, 并以其为载体制备了Pd/TiO2C电催化剂,考察了该催化剂对碱性介质中乙醇电催化氧化的活性. 结果表明,碳化导电处理的TiO2C纳米管载体能有效改善催化剂中贵金属的分散度和电极结构,从而提高催化剂的电催化活性. 对催化剂活性组分的优化实验表明, Pd/TiO2C质量比为1/1时催化剂的活性最高. 在1 mol/L KOH溶液中Pd载量均为0.3 mg/cm2的条件下, Pd/TiO2C催化剂对乙醇氧化的催化活性是Pd/C催化剂的3.8倍.     

钛金属表面结构可控多层钛酸盐纳米管薄膜的制备和结构稳定性

在水热条件下, 通过控制反应温度和氢氧化钠的浓度, 在钛金属表面得到结构可控的多层钛酸盐纳米管薄膜. 根据扫描电子显微镜和高倍透射电子显微镜的观测结果, 认为钛金属表面多层钛酸盐纳米管薄膜的形成经历以下4个阶段: (1) 钛金属的水合和碱性钛酸盐水凝胶的生成; (2) 碱性钛酸盐水凝胶分解并形成层状Na₂Ti₃O₇; (3) 层状Na₂Ti₃O₇的生长; (4) 层状Na₂Ti₃O₇的劈裂和多层卷曲成轴形成纳米管. 研究了薄膜形成后机械处理对薄膜形貌和结构稳定性的影响, 并利用超声的方法实现了多层膜的层分离.     

Coadsorption of horseradish peroxidase with thionine on TiO2 nanotubes for biosensing

In this study, we investigate the coadsorption of protein with thionine on TiO(2) nanotubes for biosensor design. The TiO(2) nanotube arrays fabricated by anodic oxidation of titanium substrate possess large surface areas and good uniformity and conformability and are ready for enzyme immobilization. Electrochemical and spectroscopic measurements show that the TiO(2) nanotube arrays provide excellent matrixes for the coadsorption of horseradish peroxidase (HRP) and thionine and that the adsorbed HRP on these TiO(2) nanotube arrays effectively retains its bioactivity. The immobilized thionine can be electrochemically reduced but cannot be reoxidized in the electrode potential range between -0.7 and 0.0 V. The addition of H(2)O(2) leads to the biocatalytic oxidation of the reduced thionine in the presence of HRP, resulting in developing a novel H(2)O(2) sensor with good stability and reproducibility. The fabricated TiO(2) nanotubes offer a stage for further study of immobilization and electrochemistry of proteins. The proposed method opens a way to develop biosensors using nanostructured materials with low electrical conductivity.     

Plate, wire, mesh, microsphere, and microtube composed of sodium titanate nanotubes on a titanium metal template

Sodium titanate nanotube/titanium metal composites were synthesized by hydrothermal treatment of titanium metals with various morphologies such as plate, wire, mesh, microsphere, and microtube at 160 degrees C in aqueous NaOH solution and by the subsequent fixation treatment by calcination at 300 degrees C. The surface of the composite was covered with sodium titanate nanotubes with a diameter of approximately 7 nm, and the core part of the composite was titanium metal phase. The raw titanium metal acts as a template or a morphology-directing agent of micrometer size or more to arrange the nanotubes as well as a titanium source for the formation of nanotubes. The concentration of titanium species increases in the reaction solution as the dissolution of titanium metal is accelerated by the reaction between titanium and OH-. Furthermore, with an increase in concentration of titanium species in the reaction solution, the titanium species are re-precipitated as sodium titanate nanotubes onto the titanium metal. Titanium metal with a large surface area and volume can form sodium titanate nanotubes on the surface of the titanium metal, though titanium metal with a small volume and surface area tends to dissolve with the hydrothermal treatment. Even in the synthesis using titanium metal with a small volume and surface area, sodium titanate nanotubes are formed and cover the surface of the titanium metal by adding another titanium metal as a source of titanium species in the reaction solution.     

Symmetry and stability of nanotubes based on titanium dioxide

The process of rolling a monolayer of bulk crystal with biperiodical planar lattice to the nanotube was analyzed. It was shown by an example of the carbon nanotubes how the tube symmetry can be revealed through the analysis of symmetry of graphene layers (the layer group with a hexagonal planar lattice) and its changes at the rolling to form the tube. The developed approach can be used to analyze the symmetry of any nanotube. A computer program we developed is discussed that allows to determine the nanotube symmetry using the data on the symmetry and coordinates of the atoms in the nanolayer and get the coordinates of the atoms in the unit cell of the nanotube which can be used for the further quantum-chemical calculations. The method and results of ab initio calculations of the titanium dioxide monolayer stability in the LCAO basis optimized for the bulk crystal, using the hybrid exchange-correlation potential PBE0 are presented. Symmetry properties of nanotubes obtained by rolling the three- and six-plane monolayers (101) and (001) of anatase are discussed. Atomic and electronic structure of TiO₂ nanotubes found by geometry optimization is analyzed. It is shown that titanium dioxide nanotubes based on the three-plane monolayers with hexagonal and square lattice are approximately of the same stability. The data on the stability of nanotubes are essential for the synthesis of new nanomaterials based on titanium dioxide.