红外辐射多相复合粉体常温发射率的提高及波段宽化

通过多相成分分析, 以镁铝硝酸盐、正硅酸乙酯、钛酸四丁酯和氧氯化锆等为原料, 采用溶胶\|凝胶燃烧法合成了新型复相氧化物粉体, 研究了Ni和Fe离子掺杂及粉体细化对红外辐射率的提高及波段宽化的影响. XRD物相分析发现, 在1100～1200 ℃范围内煅烧可获得结晶良好的氧化物粉体, 该粉体的结构为堇青石及金红石等多相结构. 采用碳酸氢铵为pH调节剂与使用氨水相比, 粒子中位粒径有显著减小. 红外辐射性能显示, 在1～22 μm的宽波段内, 该复合粉体均具有很高的红外发射率, 在10 μm附近其红外发射率达到98%. 同时Ni及Fe离子的掺杂及粉体细化可引起堇青石晶格畸变, 增强了材料的非简谐效应, 从而有利于复合粉体红外辐射率的提高.     

适用小分子化合物MALDI分析的基质研究

基质辅助激光解吸电离技术（matrix assisted laser desorption/ionization,MALDI）是20世纪80年代发展起来的一种应用于质谱分析的电离化技术。MALDI技术在生物大分子的分析和检测方面获得了良好的应用。由于受有机基质分子的干扰,MALDI在小分子化合物分析方面的应用受到很大的限制。近年来为解决这一问题,一些用于MALDI分析的新型材料被设计和开发出来。这些新型材料主要包括：碳、硅、纳米金属等无机材料和新型有机分子等。除此之外,在传统基质中添加表面活性剂和对分析物衍生化等方法也被成功应用于小分子化合物的MALDI质谱分析中。本文对这些可应用于小分子化合物分析的新型MALDI基质进行了综述和展望。     

水在纳米管道中流动行为的分子动力学模拟

采用分子动力学方法模拟了纳米管道内水分子的流动行为. 考察了压强差、 管道直径和管道长度对通量的影响, 验证了流体在直径为2～2.8 nm管道中的流动行为符合Hagen-Poiseuille(HP)方程. 研究发现, 末端效应具有长度依赖性, 对于较短的管道其末端效应更为显著. 为了深入了解真实非均匀管道的流动行为, 使用直径不同的2种管道以不同的连接顺序组合成4种非均匀管道模型, 最终得到了不同的流量. 提出了二元管道模型, 对非均匀管道内的流动行为进行了初步探讨.     

Aphanalides A–H,ring A-seco limonoids from the fruits of Aphanamixis polystachya

Eight new ring A-seco limonoids, aphanalides A–H (1–8) were isolated from the fruits of Aphanamixis polystachya. Aphanalides A–C (1–3) are the first examples of ring A-seco limonoids with an unusual oxetane ring between C-7 and C-14. The structures of aphanalide A (1) and aphanalide C (3) were confirmed by single-crystal X-ray studies. Their structures including absolute stereochemistry were established on the basis of extensive NMR spectroscopic analysis, by comparison of experimental and calculated electron circular dichroism (ECD) and by X-ray diffraction, representing the first report of assignment of absolute configuration of such type ring A-seco limonoids. The biogenetic origin of aphanalides A–D (1–4) from aphanalides E–H (5–8) was also postulated.     

聚合物前驱体3D打印制备高性能陶瓷

3D打印制备陶瓷可以实现结构-材料设计一体化,为复杂形状陶瓷材料快速成型提供了新途径。但是传统的3D打印制备陶瓷是以陶瓷粉末或陶瓷颗粒为打印材料,存在陶瓷构件尺寸精度差、表面光洁度低和力学性能不佳等问题。近年来,以聚合物前驱体为打印材料,通过3D打印成型、高温裂解等工艺制备高性能陶瓷技术的出现为改善这些不足提供了新方法,成为3D打印陶瓷领域的研究热点。本文概述了聚合物前驱体3D打印制备高性能陶瓷的研究进展,重点阐述了本体聚合物前驱体、聚合物前驱体/光敏化合物、聚合物前驱体/巯基化合物、光敏基团改性聚合物前驱体、增强体/聚合物前驱体五种典型材料体系的研究现状,并对其今后的发展方向进行了展望。     

A novel intumescent flame retardant imparts high flame retardancy to epoxy resin

Intumescent flame retardant (IFR) has received the considerable attention ascribed to the inherent advantages including non‐halogen, low toxicity, low smoke release and environmentally friendly. In this work, a novel charring agent poly (piperazine phenylaminophosphamide) named as PPTA was successfully synthesized and characterized by Fourier transform infrared spectra (FTIR) and X‐ray photoelectron spectroscopy (XPS). Then, a series of flame‐retardant EP samples were prepared by blending with ammonium polyphosphate (APP) and PPTA. Combustion tests include oxygen Index (LOI), vertical Burning Test (UL‐94) and cone calorimeter testing,these test results showed that PPTA greatly enhances the flame retardancy of EP/APP. According to detailed results, EP containing 10 wt% APP had a LOI value of 30.2%,but had no enhancement on UL‐94 rating. However, after both 7.5 wt% APP and 2.5 wt% PPTA were added, EP‐7 passed UL‐94 V‐0 rating with a LOI value of 33.0%. Moreover, the peak heat release rate (PHRR) and peak of smoke product rate (PSPR) of EP‐7 were greatly decreased. Meanwhile, the flame‐retardant mechanism of EP‐7 was investigated by scanning electron microscopy (SEM), thermogravimetric analysis/infrared spectrometry (TG‐IR) and X‐ray photoelectron spectroscopy (XPS). The corresponding results presented PPTA significantly increased the density of char layer, resulting in the good flame retardancy.     

Solventless Formation of G‐Quartet Complexes Based on Alkali and Alkaline Earth Salts on Au(111)

Template cations have been extensively employed in the formation, stabilization and regulation of structural polymorphism of G‐quadruplex structures in vitro. However, the direct addition of salts onto solid surfaces, especially under ultra‐high‐vacuum (UHV) conditions, to explore the feasibility and universality of the formation of G‐quartet complexes in a solventless environment has not been reported. By combining UHV‐STM imaging and DFT calculations, we have shown that three different G‐quartet‐M (M: Na/K/Ca) complexes can be obtained on Au(111) using alkali and alkaline earth salts as reactants. We have also identified the driving forces (intra‐quartet hydrogen bonding and electrostatic ionic bonding) for the formation of these complexes and quantified the interactions involved. Our results demonstrate a novel route to fabricate G‐quartet‐related complexes on solid surfaces, providing an alternative feasible way to bring metal elements to surfaces for constructing metal–organic systems.     

BEM for simulation of a 2D elastic body with randomly distributed circular inclusions

Based on our 2D BEM software THBEM2 which can be applied to the simulation of an elastic body with randomly distributed identical circular holes, a scheme of BEM for the simulation of elastic bodies with randomly distributed circular inclusions is proposed. The numerical examples given show that the boundary element method is more accurate and more effective than the finite element method for such a problem. The scheme presented can also be successfully used to estimate the effective elastic properties of composite materials. Project supported by the National Natural Science Foundation of China (No. 19772025).     

Multi-scale Fractured Coal Gas–Solid Coupling Model and Its Applications in Engineering Projects

With coal mining entering the geological environment of “high stress, rich gas, strong adsorption and low permeability,” the difficulty of joint coal and gas extraction clearly augments, the risk of solid–gas coupling dynamic disasters greatly increases, and the underlying mechanisms become more complex. In this paper, based on the characteristics of coal’s multi-scale structure and spatiotemporal variation, the multi-scale fractured coal gas–solid coupling model (MSFM) was built. In this model, the interaction between coal matrix and its fractures and the mechanical characteristics of gas-bearing coal were considered, as well as their coupling relationship. By MATLAB software, the stress–damage–seepage numerical computation programs were developed, which were applied into Comsol Multiphysics to simulate gas flow caused by coal mining. The simulation results showed the spatial variability of coal elastic modulus and cross-flow behaviors of coal seam gas, which were superior to the results of traditional gas–solid coupling model. And the numerical results obtained from MSFM were closer to the measured results in field, while the computation results of traditional model were slightly higher than the measured results. Furthermore, the MSFM in a large scale was verified by field engineering project.