ChemInform Abstract: A New n = 4 Layered Ruddlesden—Popper Phase K2.5Bi2.5Ti4O13 Showing Stoichiometric Hydration.

Polycrystalline K_2.5Bi_2.5Ti₄O₁₃ (I) is prepared by solid state reaction of KNO₃, Bi₂O₃, and TiO₂ (Al₂O₃ crucible, 750 °C, 16 h).     

S掺杂的还原态TiO2-x的制备及其可见光催化性能

作为一种稳定、价廉的光催化剂,TiO2被广泛应用于各种污染物的降解;但是,较大的宽禁带(~3.2 eV)和较低的电子迁移率不仅使TiO2很难吸收可见光,而且光生电子和空穴的复合几率高,从而导致TiO2的总体光电效率不高.因此,设计能够被可见光激发、并具有快速光生电子传输的TiO2一直是研究热点.研究表明,Ti3+自掺杂的TiO2(还原态TiO2-x)不仅能够被可见光激发,而且使TiO2具有良好的电子导电性,从而有利于提高TiO2的光电转换效率.另外,非金属元素的掺杂能够减小TiO2的禁带宽度,使TiO2能够响应可见光并具有良好的可见光催化性能,其中S元素的掺杂被广泛研究.目前,S掺杂纳米TiO2的制备通常采用TiS2,单质S,硫脲、二甲亚砜等为S源,但这类原料通常价格昂贵或者具有一定的毒性,因而实际应用受到限制.而制备Ti3+自掺杂TiO2的方法大都是基于"还原法",在真空或强还原性气氛如H2,CO中加热TiO2,或采用高能粒子(电子、氩离子)轰击.在实际应用中,这些方法存在步骤多、条件苛刻、反应时间长和设备昂贵等不足.而且,还原法反应通常发生在颗粒的表面,形成的Ti3+很容易被空气和水中的溶解O2氧化,降低材料的稳定性.虽然在温和的液相中还原Ti4+可用于制备Ti3+掺杂的TiO2,但是由于反应过程中有副产物生成,需要进行后续处理才能得到纯的Ti3+自掺杂TiO2.因此,设计一种简单的制备S掺杂还原态TiO2-x光催化剂仍具有十分重要的意义.前期我们采用H2O2氧化TiH2得到不同状态的前驱体凝胶,然后进行不同方式的后处理得到Ti3+自掺杂的纳米TiO2.本文以TiH2和H2O2反应得到的黄色前驱体凝胶为Ti源,以价格低廉、无毒、稳定的二氧化硫脲为S源和还原剂,采用不同的方法制备了S掺杂的还原态TiO2-x光催化剂.本文初步研究了在凝胶中加入二氧化硫脲后进行水热处理,以及将干燥的凝胶粉末与二氧化硫脲混合热处理对所得产物的影响.并与纯的TiO2、还原态TiO2-x和S掺杂TiO2的光吸收、电化学、光催化性能进行对比研究.采用X射线衍射、透射电子显微镜、高分辨透射电子显微镜、X-射线光电子能谱、紫外-可见漫反射光谱、比表面分析和电化学工作站等技术对产物的结构、形貌和光电性能进行了表征.以罗丹明B(RhB)溶液为模拟废水,考察样品的可见光催化性能.结果表明,不同的后续处理方式不仅影响S掺杂TiO2-x的结晶性和形貌,而且影响产物的光吸收性能和电子传输性能,从而使不同条件下所得产物的可见光催化性能不同.其中,采用热处理方式得到的S掺杂TiO2-x样品在可见光下降解RhB的速率分别是纯的TiO2,TiO2-x和S掺杂TiO2的31,2.5和3.6倍,而且样品具有良好的循环稳定性.     

Ce掺杂K_2La_2Ti_3O_(10)催化剂的可见光高效催化制氢的研究

采用高温固相法合成了铈掺杂的K2La2Ti3O10催化剂,利用X射线衍射(XRD)、紫外-可见漫反射(UV-visDRS)、透射电镜(TEM)和X射线光电子能谱(XPS)对催化剂进行了表征.考察了催化剂的可见光催化分解甲醇水溶液制氢的活性,并对可见光催化机理进行了分析.研究表明,铈的掺杂没有改变K2La2Ti3O10的微晶结构,并使催化剂粒径有所减小.紫外可见漫反射分析表明禁带宽度为2.3eV左右,对可见光具有较高吸收.XPS表明La和Ti为+3和+4价,而Ce则是+3和+4的混合价态.担载2wt%Pt后,在可见光下光催化活性大大提高,当铈的掺杂量为0.5mol%(即Ce取代La的摩尔百分量)时,光催化活性达到最大,产氢速率为0.05mmol/h;光照5h后产氢量为0.22mmol,而纯K2La2Ti3O10的产氢量只有0.037mmol.     

Numerical analysis of the output power of the injection-locked cw Ti:sapphire lasers

The optimization analysis of the output power of the injection-locked cw Ti:sapphire lasers is presented based on the fact that the injection-locked and free-running lasers almost have the same maximum output power. With the modified Ti:sapphire laser model, the dependences of the threshold and slope efficiency on the ring cavity and crystal parameters are studied through the numerical calculations, which clarify the roles of various parameters in affecting the output power. Our calculated results are in good agreement with the reported experimental data for the laser at 756 nm. Therefore our numerically calculated results could be used as a guideline for designing and optimizing such kind of the lasers.     

Electrochemical hydrogen storage properties of melt-spun Ti0.9Zr0.1V0.2Ni1.5La0.5 alloy

The Ti_0.9Zr_0.1V_0.2Ni_1.5La_0.5 alloy samples were synthesized by melt-spinning technique at the different wheel velocity (cooling rate), and the structure and electrochemical hydrogen storage properties were investigated. The result indicated that the structure of the melt-spun ribbons mainly contains C14 Laves phase and V-based solid solution phase. The discharge capacity, cyclic stability, high-rate discharge ability and electrochemical kinetic of the alloy electrodes are correlated with the cooling rate (wheel velocity), and the maximum discharge capacity is over 200 mA·h/g at the wheel velocity of 20 m/s.     

Influence of Ti/TiAlN-multilayer designs on their residual stresses and mechanical properties

In this research work, Ti/TiAlN multilayers of various designs were deposited onto substrates pretreated by different etching procedures. The influence of multilayer design and substrate pretreatment on multilayers adhesion, hardness, wear and friction coefficients was systematically analyzed and correlated with residual stresses of these multilayers as well as with residual stresses on the coating-near substrate region, which were analyzed by synchrotron X-ray diffraction at HZB-BESSYII. These investigations show that the adhesion can be improved by a specific etching procedure, which cause increased compressive stress in the coating-near the substrate region. Additionally, it was found, that the multilayer with the thickest ceramic layers has the highest hardness and the lowest wear coefficients as well as the lowest compressive residual stress within studied multilayers.     

Microstructure and tribological behaviors of Ti6Al4V alloy treated by plasma Ni alloying

Ni modified layer was prepared on surface of the Ti6Al4V substrate by plasma surface alloying technique. Surface morphology, micro-structure, composition distribution, phase structure, and microhardness of the Ni modified layer were analyzed. Tribological performance of the Ni modified layer and Ti6Al4V substrate was investigated by using pin-on-disc tribometer. The results indicate that roughness of the Ni modified layer was increased due to formation of the micro-convex on the modified surface. The concentration of Ni gradually decreased from the surface to interior. The maximum content of Ni atoms was nearly 90%. The modified layer was composed of TiNi, Ti2Ni and Ti phases. The maximum microhardness of the Ni modified layer was about 677 HV_0.025 which was increased about two-fold of microhardness of the control Ti6Al4V substrate. Wear resistance of the Ni modified layer was improved obviously, and showed micro-abrasion wearing. The strengthened mechanism of the as-treated Ti6Al4V alloy is discussed.     

(Ti,Al,Si,C)N nanocomposite coatings synthesized by plasma-enhanced magnetron sputtering

Materials’ surface service property could be enhanced by transition metal nitride hard coatings due to their high hardness, wear and high temperature oxidation resistance, but the higher friction coefficient (0.4-0.9) of which aroused terrible abrasion. In this work, quinternary (Ti,Al,Si,C)N hard coating 3-4 μm was synthesized at 300 °C using plasma enhanced magnetron sputtering system. It was found that the coating's columnar crystals structure was restrained obviously with the increase of C content and a non-columnar crystals growth mode was indicated at the C content of 33.5 at.%. Both the XRD and TEM showed that the (Ti,Al,Si,C)N hard coatings had unique nanocomposite structures composed of nanocrystalline and amorphous nc-(Ti,Al)(C,N)/nc-AlN/a-Si₃N₄/a-Si/a-C. However, the coatings were still super hard with the highest hardness of 41 GPa in spite of the carbon incorporation. That a-C could facilitate the graphitization process during the friction process which could improve the coating's tribological performance. Therefore, that nanocomposite (Ti,Al,Si,C)N coatings with higher hardness (>36 GPa) and a lower friction coefficient (<0.2) could be synthesized and enhance the tribological performance and surface properties profoundly.     

Room temperature 2 μm Tm,Ho : YLF laser

We present the results obtained with a Tm,Ho : YLF crystal, grown in the new crystals growth facility realized in the Dipartimento di Fisica of the Università di Pisa. The 2 μm laser performance has been studied for three different pump sources, a Ti : Sapphire, a diode—tuned at 792.7 nm—and a Co : MgF₂ laser, tuned at 1.682 μm.