天花粉蛋白的化学VI.用液光拉曼光谱研究天花粉蛋白的二级结构

由天花粉蛋白的水和重水溶液的激光拉曼光谱,测得酰胺III谱带1240cm[-1]和酰胺I谱带1632,1660cm[-1]对CH2弯曲模式1448cm[-1]的强度比值,按Lippert等建立的方程组作定量计算,求得天花粉蛋白的二级结构含量为α-螺旋43.5%,β-折叠31.3%和无序25.2%,它们与4A分辨率天花粉蛋白单晶X射线衍射法的结果相一致,同时,研究了上述溶液的冻干粉状固体的二级结构,经过冻干,使其中约10%的β-折叠转变成无序构象,而α-螺旋含量无明显变化,在水溶液中,由测得的I850/I830比值计算,天花粉蛋白中的酪氨酸残基约有805呈"暴露式"。     

[Mo2O2S2(S2)2][2-]的振动光谱研究

本文测定了原子簇化合物[Mo2O2S2(S2)2][2-]的红外和拉曼光谱,并在乙腈溶液中测得其共振拉曼光谱和退偏振比。利用X光晶体结构数据,对此阴离子的伸缩振动作了简化的正则坐标分析计算。所得结果可以帮助分析和归属一些Mo-Fe-S原子簇化合物的振动光谱。     

稀土(III)三硬脂酸盐LB膜的制备及结构研究

用直接在5×10^-^5mol.dm^-^3稀土(III)氯化物水溶液的液面上铺展稀土(III)三硬脂酸盐(简称LnSt~3)的方法,在疏水光学玻璃片上连续沉积了44层以上的含稀土(III)(La、Nd、Sm、Eu、Tb)硬脂酸盐LB膜,转移比为0.7-0.8。低角度X射线衍射(2θ=0.3-14ⅲ)结果表明,膜的结构为高度有序的层状结构,相邻稀土离子面的间距为4.7-4.8nm。X射线光电子能谱(XPS)证实了五种膜中分别含有La、Nd、Sm、Eu和Tb元素。此外,还对LnSt~3LB膜进行了红外光谱考察,表明在亚相中加入一定浓度的稀土离子能有效地抑止界面上LnSt~3的水解作用,为制备含稀土(III)离子的优质LB膜提供了依据。     

土木香内酯和异土木香内酯与共轭二烯的Diels-Alder反应

本文以土木香根中分离得到的土木香内酯(1)和异土木香内酯(2)为原料, 分别与环戊二烯(3)、螺[2.4]-4,6-庚二烯(4)、呋喃、蒽或丙烯醛进行Diels-Alder反应, 发现和2只与3或4发生反应, 未能得到1和2与呋喃、蒽或丙烯醛的反应产物。X射线单晶衍射法确定1或2与3的反应产物的构型, 应用高分辨核磁共振谱NOE方法确定1或2与4的反应产物的构型。     

N,N'-乙二水杨酰胺合铜(II)酸根和N,N'-1,2-丙二水杨酰胺全铜(II)酸根的双核Cu(II)-Fe(III)配合物的合成和磁性

本文合成了四个新型双核配合物、[Cu(samen)Fe(L)Cl]和[Cu(sampn)Fe(L)Cl]。经元素分析、IR, 电导、磁性测量等手段推定配合物具有酚氧桥结构, Cu(II)及Fe(III)的配位环境分别为平面四方及四角锥的构型, Fe(III)离子的自旋态S=3/2。测定了配合物[Cu(samen)Fe(L)Cl]的变温磁化率(4-300K), 参数J和θ值表明两个双核配合物中金属离子之间有中等程度的反铁磁性超交换作用和双核单元之间有弱的分子间相互作用。     

稀土胺羧酸配合物的研究 I. {[MnGd(DTPA)(H2O)5]2·H2O}n配合物的合成和晶体结构

本文首次合成了{MnLn(DTPA)(H2O)5]·H2O}n异核链式配合物(Ln=Gd, Er, Y)单晶,测定了{[MnGd(DTPA)(H2O)5]2·H2O]n的单晶结构。     

A Numerical Investigation on the Influence of Steel Fiber Shape and Interface Strength in Reinforced Concrete

Not all steel fiber reinforced concrete composites are equally effective in enhancing structural performance. Their mechanical behaviour strongly depends upon the reinforcement morphology as well as the properties of the interface lying between steel reinforcement and concrete matrix. Using bone-shaped short (BSS) steel fibers, instead of conventional straight short (CSS) steel fibers, to reinforce concrete has demonstrated their potential in improving toughness, ductility and energy absorbing capacity under impact significantly and simultaneously. Accomplishing a strong steel–concrete interface leads to a slight increase in composite strength but simultaneously to a significant decrease in its toughness. Due to the sensitivity of steel reinforced concrete performance on these complex geometric and material parameters, the development of a numerical tool capable of simulating accurately the composite mechanical behaviour and thus leading to optimized design solutions is desirable. The physical problem of the present work involves a typical concrete composite uniformly reinforced with steel fibers subjected to tensional loading. A micromechanical non-linear finite element formulation is utilized in order to predict the load transfer characteristics and the failure process. A linear material behaviour is assumed for the steel component; a non-linear multi-crack material response is used to describe concrete while a mix-mode bilinear behaviour is utilized for the interface providing separation of primary material phases. Numerical results are presented in terms of the global design parameters. The influence of the fiber end shape, the interface strength and the fiber volume fraction on the composite strength and toughness is addressed and consequently optimized design preferences arise.     

In situ observation of interfacial debonding process induced by matrix crack propagation in two-dimensional unidirectional model composites

Interfacial debonding behavior is studied for unidirectional fiber reinforced composites from both experimental and analytical viewpoints. A new type of two-dimensional unidirectional model composite is prepared using 10 boron fibers and transparent epoxy resin with two levels of interfacial strength. In situ observation of the internal mesoscopic fracture process is carried out using the single edge notched specimen under static loading. The matrix crack propagation, the interfacial debonding growth and the interaction between them are directly observed in detail. As a result, the interfacial debonding is clearly accelerated in specimens with weakly bonded fibers in comparison with those with strongly bonded fibers. Secondary, three-dimensional finite element analysis is carried out in order to reproduce the interfacial debonding behavior. The experimentally observed relation between the mesoscopic fracture process and the applied load is given as the boundary condition. We successfully evaluate the mode II interfacial debonding toughness and the effect of interfacial frictional shear stress on the apparent mode II energy release rate separately by employing the present model composite in combination with the finite element analysis. The true mode II interfacial debonding toughness for weaker interface is about 0.4 times as high as that for a stronger interface. The effect of the interfacial frictional shear stress on the apparent mode II energy release rate for the weak interface is about 0.07 times as high as that for the strong interface. The interfacial frictional shear stress and the coefficient of friction for weak interface are calculated as 0.25 and 0.4 times as high as those for strong interface, respectively.     

Thermal behavior of chemically treated and untreated sisal fiber reinforced composites fabricated by resin transfer molding

Using thermogravimetric analysis (TGA), the thermal behavior of sisal fibers and sisal/polyester composites, fabricated by resin transfer molding (RTM), has been followed. Chemical treatments have been found to increase the thermal stability, which has been attributed to the resultant physical and chemical changes. Scanning electron microscopy (SEM) and infrared (FT-IR) studies were also performed to study the structural changes and morphology in the sisal fiber during the treatment. The kinetic studies of thermal degradation of untreated and treated sisal fibers have been performed using Broido method. In the composites, as the fiber content increases, the thermal stability of the matrix decreases. The treated fiber reinforced composites have been found to be thermally more stable than the untreated derivatives. The increased thermal stability and reduced moisture behavior of treated composites have been correlated with fiber/matrix adhesion.     

LaI3.6C11H12ON2的合成和表征

用溶解度等温法研究了LaI3-C11H12ON2(安替比林)-H2O三元体系在0℃时的相平衡,体系中有组成为LaI3.6C11H12ON2的二元复合物生成。本文还确定了该复合物的制备条件,测定了它的一些性质,并对其结构作了初步分析。