稀土元素的摩擦学研究发展概况

本文对稀土元素的摩擦学研究发展概况作了综述与讨论,主要涉及的是稀土金属及稀土无机化合物和稀土配合物作为润滑油、脂及润滑涂层的添加剂的摩擦学特性,并对稀土无机化合物的高温润滑特性、稀土金属及其化合物在高温涂层中的应用作了简要讨论,最后还提出了稀土的摩擦学研究中当前值得注意的几个重要课题。     

基础滑移隔震体系的地震响应计算

利用随机振动理论求出了基础滑移隔震房屋在无频谱过程的白噪声过程作用下的响应特性，探讨了基础滑移隔震的振动时最佳阻尼系数取值，提出了基础最大滑移量在白噪声过程作用下的计算公式，并进行了基础滑移隔震位移量的试验测定。计算结果与试验结果表明，本文提出的基础滑移隔震体系的计算公式是可行的，为滑移隔震房屋设计证结构安全、合理提供了理论依据。     

碳钢的高应力冲击磨损行为研究

在高应力冲击磨损条件下，金属材料的磨损表面很容易形成硬度很高（ＨＶ≥１０００）的白层．采用新的试验方法，研究了碳钢在高应力冲击条件下的磨损特征，并且从分析白层的结构出发，讨论了白层的形成机制和失效模式．结果表明，材料的高应力冲击磨损质量损失与冲击次数之间具有线性关系，韧性较好的低碳钢的耐磨性比高碳钢的好，原因是硬度越高，白层在磨损过程中越容易发生剥层与剥落．白层是一种高度塑性变形层，其内部精细结构的变形特征证实了白层的塑性变形机制     

沉积温度对硬质合金表面沉积的SiC薄膜的影响

采用强电流直流伸展电弧等离子体CVD技术,以Ar、H2和四甲基硅烷(TMS)为先驱气体,在YG6硬质合金衬底表面制备了SiC薄膜。实验结果表明:随着沉积温度的升高,薄膜的致密性和平整度提高;但当沉积温度过高时,SiC薄膜的表面开始具有含非晶碳球和呈花瓣状的疏松结构。在合适的沉积温度下,SiC薄膜的致密性和平整度较好,且其具有较好的附着力和一定的强度,而这样的SiC薄膜可以阻止在金刚石涂层沉积过程中硬质合金中含有的Co对金刚石相沉积过程的有害作用。     

液相质谱测定非极性或弱极性物质的研究进展

从衍生、离子加合、离子源、裂解等方面对近年来液相质谱测定非极性或弱极性物质的研究进行综述。其中,衍生方式主要介绍了醛酮类化合物、醇类化合物、胺类化合物、烯烃与炔烃等物质的衍生方式,离子加合主要介绍了铵根离子加合等正离子加合模式与甲酸根等负离子加合模式,离子源主要介绍了大气压化学电离(APCI)、APPI、DESI三种离子源在测定非极性或弱极性物质的研究,裂解方式以三氯杀螨醇为例子。文章以实例对液相质谱测定非极性或弱极性物质的策略进行了讨论,对它们的现状和未来前景进行预测。     

活性炭负载纳米TiO_2光催化降解甲醛废水研究

甲醛对人和温血动物的毒性很强,如果人类长期饮用被甲醛污染的水源,会引发头昏、贫血以及各种神经系统疾病.为此,研究学者对甲醛废水的处理进行了很多的试验研究.目前处理甲醛废水的主要方法有:芬顿法、光催化氧化法、湿式氧化处理等高级氧化技术,二氧化氯法,蒸汽吹脱法,氧化吸附法,SBR工艺等.     

第二讲 行程问题

在小学数学应用题这一大家庭中,行程问题是其中最为重要的一类。它以丰富多彩的内容、变化多端的解法,对广大少年儿童产生着巨大的吸引力,它对提高少年儿童分析问题、解决问题的能力有着十分重要的作用,在各级各类竞赛中,它是每赛必有,并经常被当作拉开考生档次的把关题。     

双分布聚乙二醇接枝纳米二氧化硅的高效可控制备

在混合溶剂中通过"grafting to"的方法将2种分子量不同的聚乙二醇单甲醚(MPEG M_w=750,4000)接枝到氨基修饰的St?ber法二氧化硅(SiO_2-NH_2)表面,制备双分布纳米接枝复合物.采用二步法,先将带环氧端基的低分子量聚乙二醇单甲醚(MPEG-EO)与SiO_2-NH_2在甲苯溶剂中充分反应后,与高分子量的MPEG-EO在甲苯和正癸烷的混合溶剂中使用相同的反应条件和后处理方法,能便捷制备出具有双分布接枝的纳米复合物.在接枝反应体系中,分子链的链段尺寸和接枝密度之间存在着密切关系.一定的范围内,接枝密度随链段尺寸减小而增大.通过改变混合溶剂比例来调控接枝链段的尺寸,可以很好控制聚合物的接枝密度.在双分布接枝的纳米复合物中,低分子量的接枝密度为0.85 chains/nm~2,高分子量的接枝密度能达到0.40 chains/nm~2,体现出了简单、高效、可控的特点,与聚环氧乙烷(PEO)共混后分散良好,对于制备出均匀分散的纳米复合材料起到了一定的指导作用.     

Effects of preparation parameters on growth and properties of β-Ga2O3 film

The Ga$_{2}$O$_{3}$ films are deposited on the Si and quartz substrates by magnetron sputtering, and annealing. The effects of preparation parameters (such as argon-oxygen flow ratio, sputtering power, sputtering time and annealing temperature) on the growth and properties ($e.g.$, surface morphology, crystal structure, optical and electrical properties of the films) are studied by x-ray diffractometer (XRD), scanning electron microscope (SEM), and ultraviolet-visible spectrophotometer (UV-Vis). The results show that the thickness, crystallization quality and surface roughness of the $\beta $-Ga$_{2}$O$_{3}$ film are influenced by those parameters. All $\beta $-Ga$_{2}$O$_{3 }$films show good optical properties. Moreover, the value of bandgap increases with the enlarge of the percentage of oxygen increasing, and decreases with the increase of sputtering power and annealing temperature, indicating that the bandgap is related to the quality of the film and affected by the number of oxygen vacancy defects. The $I$-$V$ curves show that the Ohmic behavior between metal and $\beta $-Ga$_{2}$O$_{3}$ films is obtained at 900 ${^\circ}$C. Those results will be helpful for the further research of $\beta $-Ga$_{2}$O$_{3}$ photoelectric semiconductor.     

Improve the performance of interferometer with ultra-cold atoms

Ultra-cold atoms provide ideal platforms for interferometry.The macroscopic matter-wave property of ultra-cold atoms leads to large coherent length and long coherent time,which enable high accuracy and sensitivity to measurement.Here,we review our efforts to improve the performance of the interferometer.We demonstrate a shortcut method for manipulating ultra-cold atoms in an optical lattice.Compared with traditional ones,this shortcut method can reduce the manipulation time by up to three orders of magnitude.We construct a matter-wave Ramsey interferometer for trapped motional quantum states and significantly increase its coherence time by one order of magnitude with an echo technique based on this method.Efforts have also been made to enhance the resolution by multimode scheme.Application of a noise-resilient multi-component interferometer shows that increasing the number of paths could sharpen the peaks in the time-domain interference fringes,which leads to a resolution nearly twice compared with that of a conventional double-path two-mode interferometer.With the shortcut method mentioned above,improvement of the momentum resolution could also be fulfilled,which leads to atomic momentum patterns less than 0.6hkL. To identify and remove systematic noises,we introduce the methods based on the principal component analysis (PCA) that reduce the noise in detection close to the 1/√2 of the photon-shot noise and separate and identify or even eliminate noises.Furthermore,we give a proposal to measure precisely the local gravity acceleration within a few centimeters based on our study of ultracold atoms in precision measurements.