MOFs材料低温储氢性能研究用低温恒温器设计

设计了一种用于研究金属有机骨架(MOFs)材料低温储氢性能的低温恒温器。介绍了其设计原理及具体结构。该低温恒温器能够为多种MOFs材料提供低温宽温区范围内的温度环境,且样品更换方便。     

腈基功能化有机硅电解液添加剂对LiFePO4电池低温性能的影响

合成了一种腈基功能化有机硅化合物3-氰乙基-二乙氧基-甲基硅烷(DESCN), 并对其化学结构和电化学窗口进行了表征. 采用恒流充放电、 扫描电子显微镜(SEM)、 X射线光电子能谱(XPS)及电化学阻抗谱(EIS)等方法研究了DESCN添加剂对LiFePO₄电池低温性能的影响. 结果表明, DESCN化合物能够在电极表面参与形成更薄、 更均匀且致密的固体电解质界面(SEI)膜, 抑制电解液副反应的发生, 减小界面膜阻抗, 有利于低温下电极/电解液界面的Li⁺扩散和电荷转移, 从而提高LiFePO₄电池的低温性能.     

Fabrication of superhydrophobic surfaces on aluminum

A superhydrophobic surface was prepared on aluminum substrate. Anodization and low-temperature plasma treatment were used to create micro-nano-structure and subsequently trichlorooctadecyl-silane modified the rough surface. The result shows that the water static contact of the aluminum surface after anodization and modification by trichlorooctadecyl-silane reaches to 152.1°. A rougher surface with some micro-nano-pores and small mastoids along the edges of pores was generated when low-temperature plasma treatment was applied to anodized aluminum film, resulting in water static contact angle up to 157.8°.     

无水苯甲酸锂的合成、结构表征及热化学研究

用分析纯苯甲酸和一水氢氧化锂作为反应物, 采用水热合成法制得苯甲酸锂. 利用X射线粉末衍射、FTIR、元素分析及化学分析等方法对样品进行组成和结构表征. 采用精密自动绝热热量计测量了其在80~400 K范围内的摩尔热容, 利用最小二乘法将此温区热容实验值对折合温度进行拟合, 得到热容随温度变化的多项式方程. 通过设计合理的热化学循环, 选用0.1 mol/L HCl溶液作为量热溶剂, 利用等温环境溶解-反应热量计分别测定合成反应的反应物和产物在所选溶剂中的溶解焓, 得到反应焓Δ_rH_m⁰=-(9.75±0.27) kJ/mol. 利用Hess定律计算出苯甲酸锂的标准摩尔生成焓Δ_fH_m⁰(C₆H₅COOLi, s)=-(307.82±0.57) kJ/mol.     

Low-temperature expansion for lattice systems with many ground states

Low-temperature expansion for systems with many ground states is discussed. It is pointed out that, in general, different ground states may yield different formal perturbation expansions, and that the right expansion of the free energy is provided by ground states called here dominant.Supported in part by Grant AFOR-78-3522.     

Highly Dispersed and Nano-sized Pt-based Electrocatalysts for Low-Temperature Fuel Cells

Among metals, Pt is so far the best material to be used as anode and cathode in low-temperature fuel cells. However, Pt has the drawback of being expensive and easily CO-poisoned. Thus, to produce useful electrocatalysts, significant efforts have been made worldwide on developing Pt-based catalysts with low Pt contents as well as searching for alternative materials with high catalytic activity for anodic and cathodic reactions in low-temperature fuel cells. This article presents the development of highly dispersed and nano-sized Pt-based electrocatalysts synthesized by several new methods based on our experimental results. In the case of anode materials, our proposed new method consists of the synthesis of Pt-based nanoparticles in order to maximize their surface availability, combined with the use of secondary metals that promote the oxidations of methanol and CO. On the other hand, for the cathode materials, the use of the Pt catalysts mixed with metal oxides enhances their oxygen reduction reaction (ORR) activity. We anticipate that the highly dispersed Pt-based nanoparticles introduced in this article will improve the performance of anode and cathode for low-temperature fuel cells.     

Monolith Manganese-Based Catalyst Supported on ZrO2-TiO2 for NH3-SCR Reaction at Low Temperature

Monolith catalysts were prepared using TiO₂ and ZrO₂-TiO₂ as supports with MnO₂ as active component and Fe₂O₃ as promoter. The catalytic activities at low temperature and stability at high temperature for selective catalytic reduction of NO_x with NH₃ (NH₃-SCR) in the presence of excessive O₂ were studied after the catalysts calcined at different temperatures. The catalysts were characterized by X-ray diffraction (XRD), specific surface area measurements (BET), oxygen storage capacity (OSC), and temperature programmed reduction (H₂-TPR). The results indicated that the catalyst supported on ZrO₂-TiO₂ had excellent stability at high temperature, and possessed high specific surface area and oxygen storage capacity, and had strong redox property. The results of the catalytic activities indicated that the monolith manganese-based catalyst using ZrO₂-TiO₂ as support had evidently improved the activity of NH₃-SCR reduction reaction at low temperature, and it showed great potential for practical application.     

Sm(Val)Cl3·6H2O低温热容及热化学性质

采用精密绝热量热计测定了稀土氨基酸配合物[Sm(Val)Cl3·6H2O]在80-376 K温区的热容, 从实验热容值计算出了热力学函数(HT-H298.15和ST-S298.15). 在308 K附近, 配合物的热容出现一个大的跳跃, 可能是其玻璃化转变所致. 对该配合物进行热重测试, 得到了其可能的分解机理.     

氧等离子体低温灰化法测定生物样品灰分中易挥发元素

本文介绍了氧等离子体低温灰化法及我们设计研制的氧等离子体低温灰化装置在多种样品处理中的应用。结果表明;本法对样品中含有的易挥发元素可取得良好的回收率,仪器具有较好的适用性、可靠性。     

Yb~(3+):Y_2O_3超细粉体的低温燃烧法合成及发光性能

以稀土硝酸盐和尿素(摩尔分数为1∶3)为原料,采用低温燃烧法在点火温度为600℃,热处理温度为1 100℃,热处理时间为1 h条件下制备了Yb3+∶Y2O3超细粉体。利用X射线粉末衍射仪(XRD)、扫描电子显微镜(SEM)和荧光光谱仪(FS)对粉体进行了表征。研究了点火温度、燃料用量和热处理温度对粉体性能的影响。实验结果表明:所制备的Yb3+∶Y2O3超细粉体的粒径为15～30 nm,颗粒分散性较好,无明显团聚,且粉体的发光性能良好,发射峰位于976,1 030和1 075 nm,适合于制备Yb3+∶Y2O3透明陶瓷。