新型杂化絮凝剂PAC-PDMDAAC对染料废水的脱色光谱分析

用新型杂化絮凝剂聚合氯化铝-聚二甲基二烯丙基氯化铵(PAC-PDMDAAC)处理分散紫和活性艳红两种染料废水。杂化絮凝剂投药量为400和450mg·L~(-1)时,分散紫和活性艳红的脱色率分别达到99%和86.8%,优于聚合氯化铝(PAC)和复配型PAC-PDMDAAC。杂化絮凝剂处理分散紫的最佳pH为7~12,而处理活性艳红的最佳pH为7~9。分别对两种染料及其杂化絮体进行傅里叶红外光谱扫描,结果表明杂化絮凝剂与两种染料分子的某些基团有络合作用,杂化絮体中羟基峰增大且宽化,杂化絮凝剂对染料废水的脱色以吸附电中和为主。对染料原水以及混凝后上清液进行紫外连续扫描,两种上清液的吸光度都大大降低,同时吸收曲线波峰偏移,进一步说明电中和与吸附架桥的协同作用是脱色的主要机理。同时,杂化絮凝剂对分散紫的脱色是通过破坏醚键以及与—NH_2反应,而对活性艳红的脱色则是通过对—SO_3的置换以及对Cl-的取代。为该新型无机-有机高分子杂化絮凝剂混凝脱色效能及脱色机理研究提供新方法,具有实际意义和应用价值。     

以TEOS为硅源的聚硅硫酸铁中铁的形态分布研究

利用正硅酸乙酯代替传统硅酸钠制备活性硅酸,使之与聚合硫酸铁反应而得到聚硅硫酸铁絮凝剂。由于正硅酸乙酯水解很缓慢,容易控制,可得到铁硅分布均匀、重现性好的产物;这有利于进行聚硅硫酸铁中铁的形态研究。采用Fe-Ferron逐时络合比色法和红外光谱法研究了聚硅硫酸铁絮凝剂中铁和硅的形态分布。研究结果表明:聚硅硫酸铁絮凝剂中Fe(a)形态较多,Fe(b)和Fe(c)含量相对较少。在一定时间内,随着熟化时间的延长,Fe(a)和Fe(b)含量有所下降,Fe(c)含量有所增加;但是当熟化时间到达5d后,三种形态的变化不大。研究还显示聚硅硫酸铁絮凝剂中铁和硅的形态与其在聚合硫酸铁和聚硅酸中是不同的;聚合硫酸铁与活性硅酸并非简单的复合,而是发生了复杂的化学反应,生成了一种重现性好的新型无机高分子聚硅硫酸铁絮凝剂。     

丙烯酰胺聚合物与氧化铝晶体相互作用的分子动力学模拟

将丙烯酰胺单体分别与丙烯酸(AA)、阳离子单体丙烯酰氧乙基二甲基乙基溴化铵(DMB)、疏水性单体丙烯酸十八酯(OA)共聚,分别得到阴离子聚丙烯酰胺P(AA-co-AM)、阳离子聚丙烯酰胺P(DMB-co-AM)、非离子聚丙烯酰胺P(AM)和疏水性聚丙烯酰 胺P(OA-co-AM)等四种丙烯酰胺高分子絮凝剂. 用分子动力学方法,模拟计算了四种聚丙烯酰胺絮凝剂与氧化铝晶体(012)晶面的相互作用,以获得相应的形变能,结合能及理论排序,为阐释四种高分子絮凝剂的絮凝作用机理提供理论依据. 研究结果表明：四种聚合物分子相对Al₂O₃(012)面的初始位置均已贴近Al₂O₃(012)面,且絮凝剂分子中的O原子与Al₂O₃(012)面的Al原子之间存在强烈的相互作用;与Al₂O₃(012)晶面结合的高分子絮凝剂发生扭曲变形,但形变能远小于相应的非键作用能. Al₂O₃(012)晶面结合能的大小排序为P(DMB-co-AM)>P(OA-co-AM)>P(AA-co-AM)>P(AM), 显示四种絮凝剂中P(DMB-co-AM)的絮凝性能最佳,PAM絮凝效果最差.     

抗菌素阿莫西林荧光分析法的研究

本文提出了阿莫西林［（2S,5R,6R）-3,3-二甲基-6-［(R)-(-)-2-氨基-2-(4-羟基苯基)乙酰氨基］-7-氧化-4-硫杂-1-氮杂双环［3,2,0］庚烷-2-甲酸三水化合物］荧光分析的方法。并对影响阿莫西林荧光性质(光谱和光谱强度)的各种因素,包括pH值、表面活性剂的增效作用、无机离子的配合作用以及其他介质条件等进行了较为详细的研究。实验结果表明,阿莫西林具有良好的荧光性质,在微碱性条件下荧光发射最强,CTAB对其有增效作用,与无机离子(Mg     

超支化高分子桥联聚倍半硅氧烷复合物的NMR研究

以三羟甲基丙烷(TMP)为内核，二羟甲基丙酸(DMP)为支化单元用准一步法合成了重均分子量为12100的第四代端羟基脂肪族超支化聚酯(HBPE-G4)，用3-异氰酸酯基丙基三乙氧基硅烷(TPIC)对它进行了端基改性，并以其为桥联剂，与聚倍半硅氧烷(PMSQ)复合制备出超支化高分子桥联聚倍半硅氧烷复合物．利用固体核磁共振(NMR)，傅立叶红外(FI-IR)，分子纳米粒度分析等方法表征了改性超支化高分子和复合物的结构和反应程度，并通过测量¹³C T₁，¹H T₂，¹H T_1ρ研究了体系中各组分的运动性能，以及超支化高分子与聚倍半硅氧烷之间的相容性．     

光聚合壳聚糖基絮凝剂的光谱表征研究

由于壳聚糖的大分子键上分布着大量的氨基、羟基和N-乙酰基等活性功能基团,将其改性作为天然绿色絮凝剂越来越受到关注,但对其的接枝共聚产物的光谱学表征研究鲜有报道。因此,对壳聚糖基絮凝剂进行光谱学表征与分析研究具有重要意义。论文以壳聚糖(CS)、丙烯酰胺(AM)、二甲基二烯丙基氯化铵(DMDAAC)为接枝共聚单体,采用光聚合技术制备壳聚糖基絮凝剂CS-P(AM-DMDAAC)。采用X射线衍射(XRD)、紫外光谱(UV)、红外光谱(IR)研究其结构特征;分析了壳聚糖、丙烯酰胺、二甲基二烯丙基氯化铵及三者接枝共聚产物的X射线衍射(XRD)、紫外光谱(UV)、红外光谱(IR)的图谱特征和振动吸收峰归属。研究了壳聚糖脱乙酰度、壳聚糖浓度、阳离子度对接枝共聚产物壳聚糖基絮凝剂CS-P(AM-DMDAAC)的X射线衍射(XRD)、紫外光谱(UV)、红外光谱(IR)的影响。UV光谱和IR光谱研究结果证明CS,AM和DMDMAAC成功发生接枝共聚反应制备出CS-P(AM-DMDAAC),壳聚糖浓度增加导致其光谱对称性减弱。XRD图谱研究表明接枝共聚反应使得壳聚糖的晶型结构趋向不定型结构转变,不定型结构相比于晶型结构更易于水化,故接枝共聚产物具有更加优异的溶解性。     

PCL/SiO2杂化纳米相微结构与晶态成核生长特性

应用扫描电子显微镜、广角X射线衍射和差示扫描量热手段研究了有机高分子/无机组分间以物理次价力(氢键)键合的高分子量PCL/SiO2杂化材料纳米相微结构和PCL高分子链在该微结构环境中的结晶成核生长特性及其影响因素.研究结果表明:杂化体系中高分子/无机组分间的微相分离尺度在纳米数量级,高分子微区的平均相畴尺寸在70nm左右,无机相形态呈现不规则的颗粒状.两相均匀分布程度与体系中组分间的氢键键合强度有关.PCL杂化后结晶度减小,对应的微晶尺寸明显改变,平衡熔点随无机组成含量的增加而下降.高分子链在晶核表面折叠形成结晶结构所需的能量增加.这一结果归因于无机非晶SiO2和键合强度的影响.     

紫外光引发聚合聚丙烯酰胺絮凝剂的研究与发展

聚丙烯酰胺是一种重要的高分子聚合物,它和它的衍生物常用作有效的絮凝剂、增稠剂等,在日常生活及工业生产中应用广泛。紫外光引发聚合技术是一种绿色环保的聚合技术,目前已经在生物医药材料、纳米材料等领域取得了良好的应用。在絮凝剂制备领域,由紫外光引发制备的聚丙烯酰胺絮凝剂具有能耗低、时间短、操作简单的优势。论文综述了2012至2016年紫外光引发聚丙烯酰胺的合成、表征及其应用。     

离子注入在陶瓷材料中的应用

随着科学技术的发展,离子注入的应用范围在不断扩大.它除了广泛应用于半导体、金属材料的表面改性外,在加工绝缘材料(如玻璃、陶瓷和高分子聚合物等)方面也表现出有一定的发展潜力,有可能在光的波导、磁泡储存,铁电陶瓷、光敏陶瓷、高温陶瓷、表面导电聚合物和表面催化等方面发挥作用.本文对离子注入在陶瓷材料中的一些应用及最近取得的一些成果作一综述.主要包括离子注入陶瓷材料的表面改性、离子注入合成陶瓷材料和离子轰击加强金属(陶瓷)/陶瓷界面的“缝合”三个方面. 一、离子注入陶瓷材料的表面改性 陶瓷泛指整个硅酸盐材料,是无机非金…     

超晶格高分子—无机纳米复合物

近年来，具有规整结构的纳米复合材料很受人们关注；利用有机－无机相间具有的强相互作用进行有序组装，可实现纳米复合材料结构与形态的微观调控．文章主要讨论了最近纳米复合物领域中的超晶格高分子－无机纳米复合物     

Photonic band gaps in two-dimensional photonic crystals of core-shell-type dielectric nanorod heterostructures

A new type of two-dimensional photonic crystal (PC) called core-shell-type PC composed of a nanorod heterostructure array in a square or triangular lattice such that a dielectric nanorod is covered by a thin interfacial layer is studied. Using the plane-wave numerical expansion method, we study the modification of the band gap spectrum when the nanorods are covered by other material, and reveal that the photonic band gap is considerably enhanced in size for both square and triangular lattice. The effects of structural parameters on the band gaps are also studied. The results show that there exist optimal parameters to open large gaps, and TE (Transverse-electric) band gaps are favored in a triangular lattice.     

Studies of diamond-like carbon （DLC） films deposited on stainless steel substrate with Si/SiC intermediate layers

In this work, diamond-like carbon （DLC） films were deposited on stainless steel substrates with Si/SiC intermediate layers by combining plasma enhanced sputtering physical vapour deposition （PEUMS-PVD） and microwave electron cyclotron resonance plasma enhanced chemical vapour deposition （MW-ECRPECVD） techniques. The influence of substrate negative self-bias voltage and Si target power on the structure and nano-mechanical behaviour of the DLC films were investigated by Raman spectroscopy, nano-indentation, and the film structural morphology by atomic force microscopy （AFM）. With the increase of deposition bias voltage, the G band shifted to higher wave-number and the integrated intensity ratio ID/IG increased. We considered these as evidences for the development of graphitization in the films. As the substrate negative self-bias voltage increased, particle bombardment function was enhanced and the sp^3-bond carbon density reducing, resulted in the peak values of hardness （H） and elastic modulus （E）. Silicon addition promoted the formation of sp^3 bonding and reduced the hardness. The incorporated Si atoms substituted sp^2- bond carbon atoms in ring structures, which promoted the formation of sp^3-bond. The structural transition from C-C to C-Si bonds resulted in relaxation of the residual stress which led to the decrease of internal stress and hardness. The results of AFM indicated that the films was dense and homogeneous, the roughness of the films was decreased due to the increase of substrate negative self-bias voltage and the Si target power.     

Ti掺杂NbSe2电子结构的第一性原理研究

采用基于密度泛函理论框架下的第一性原理平面波超软赝势方法, 计算了理想2H-NbSe₂和Ti掺杂2H-NbSe₂晶体的几何结构及电子结构; 对掺杂前后超胞的能带图、态密度及分波态密度图进行了分析. 结果表明, 掺杂后费米能级附近能量区域的电子态密度出现了较高的峰值, 且费米能级位置发生了改变. 理论上可以认为Ti的掺杂会使得NbSe₂的导电性增强, 有利于开发新型的电接触复合材料.     

The application of reed-vibration mechanical spectroscopy for liquids to detect chemical reactions of an acrylic structural adhesive

There remain a number of unsolved problems about chemical reactions, and it is significant to explore new detection methods because they always offer some unique information about reactions from new points of view. For the first time, the solidification course of a modified two-component acrylic structural adhesive is measured by using reed-vibration mechanical spectroscopy for liquids （RMS-L） in this work, and results show that there are four sequential processes of mechanical spectra with time. The in-depth analyses indicate that RMS-L can detect in real-time the generation and disappearance of active free radicals, as well as the chemical cross-link processes in the adhesive. This kind of real-time detection will undoubtedly facilitate the study of the chemical reaction dynamics controlled by free radicals.     

Variation of the electronic properties of zigzag boron nitride nanotubes by Al-doping: a DFT study

Boron nitride nanotubes (BNNTs) are semiconductors with a wide band gap. In comparison with carbon nanotubes (CNTs), BNNTs have higher chemical stability, excellent mechanical properties and higher thermal conductivity. In this paper, we study the effect of diameters and substituting B and N atoms of various zigzag BNNTs with Al, on structural and electronic properties of BNNTs in solid state using the density functional theory method. The results of calculations of density of states and band structure (band) showed that the band gap between the valence and conduction level increases as a result of the enhancement of tube diameter of BNNTs. Finally, the results showed that the electronic properties of the pristine BNNTs can be improved by doping Al atom in the zigzag configuration of tubes.     

Synthesis and comparative study of optical and electrical properties of Au-doped carbon nanotubes prepared in different reaction media

We introduce the synthesis, characterization and physical properties of gold (Au) doped multiwalled carbon nanotubes (MWCNTs) in different reaction media. In order to dope MWCNTs with Au nanoparticles (NPs), first functionalized carbon nanotubes (f-MWCNTs) were prepared. The reduction of gold (III) chloride trihydrate for synthesizing Au NPs in the presence of f-MWCNTs was performed by using sodium citrate as a reducing agent. The produced nanocomposites were characterized using FTIR, XRD and TEM analyses to explore their chemical structures and morphologies. All of the samples have been characterized by TGA and resultantly, the composite made into ethylene glycol exhibited the most concentration of Au NPs into the composite network. This work probes the optical characteristics, such as UV–vis absorption, and optical band gap. Hall effect analyses declared some pleasing variations in electrical characteristics. Remarkably, the n-type doping of Au NPs in the p-type MWCNTs’ network led to a downshift of the Fermi level. This process increased the doped samples electrical conductivity. The results indicated that modification of MWCNTs with Au NPs has generally an important role in decreasing the band gap and increasing the electrical activity of MWCNTs. Our research outcomes provide a new vision into how different reaction media could affect the characteristics of MWCNT/Au nanocomposites. We discovered that ethylene glycol could be considered as a perfect reaction medium for preparation of high-quality doped CNTs with excellent physical properties. Our effort opens up the door to far more investigations on the role of the reaction medium in products’ characteristics.     

High-resolution electron microscopy for heterogeneous catalysis research

Heterogeneous catalysts are the most important catalysts in industrial reactions. Nanocatalysts, with size ranging from hundreds of nanometers to the atomic scale, possess activities that are closely connected to their structural characteristics such as particle size, surface morphology, and three-dimensional topography. Recently, the development of advanced analytical transmission electron microscopy(TEM) techniques, especially quantitative high-angle annular darkfield(HAADF) imaging and high-energy resolution spectroscopy analysis in scanning transmission electron microscopy(STEM) at the atomic scale, strengthens the power of(S)TEM in analyzing the structural/chemical information of heterogeneous catalysts. Three-dimensional reconstruction from two-dimensional projected images and the real-time recording of structural evolution during catalytic reactions using in-situ(S)TEM methods further broaden the scope of(S)TEM observation. The atomic-scale structural information obtained from high-resolution(S)TEM has proven to be of significance for better understanding and designing of new catalysts with enhanced performance.     

Design of Two 8-Channel Optical Demultiplexers Using 2D Photonic Crystal Homogeneous Ring Resonators

ABSTRACT

Ring resonators have always been referred to as a highly flexible structure for designing optical devices. In this paper, we have designed and evaluated two 8-channel optical demultiplexers using photonic crystal ring resonators. The purpose of this study is to investigate the flexibility of this type of resonator for designing and manufacturing optical devices based on photonic crystals. To the extent that we have investigated the literature, there is no report so far on such a study. For this purpose, two structures with the same structural parameters, but only with a difference in the type of lattice constant (square or triangular) are used. Both structures have a common photonic band gap within a proper range for telecommunication applications used in wavelength-division multiplexing (WDM) systems. Both designed structures have an average crosstalk of ?26 dB. For the demultiplexer structure with a square lattice constant, the quality factor and the transmission coefficient are 3,046 and 93.7% respectively, and its channel spacing is 1.97 nm. For the structure with a triangular lattice constant, the quality factor and the transmission coefficient are 1577.7 and 94.5%, respectively and its channel spacing is equal to 4 nm. To obtain the photonic band gap of the structures, the plane wave expansion (PWE) method is used and the output spectrum of the structures is obtained using the finite-difference time-domain (FDTD) method. The good results obtained in this study is through designing and simulating optical demultiplexer structures only by creating a change in the type of lattice constant used. This undoubtedly justifies the high flexibility of ring resonators, when used in the design of optical devices, as well as their suitability for the use in WDM systems     

冷等离子体强化制备金属催化剂研究进展

冷等离子体属于非热平衡等离子体，具有较高的电子能量和较低的气体温度，是一种制备金属催化剂的绿色新方法.等离子体强化制备金属催化剂包含复杂的物理和化学多相反应.一方面，等离子体提供的高活性环境不但可以加速化学反应，使反应时间从数小时缩短至数分钟，还可以使热力学或者动力学上不可行的反应发生，实现非常规制备；另一方面，等离子体强化制备过程中，在介观尺度上等离子体对相接触行为的影响，可使获得的金属催化剂结构区别于传统方法制备的催化剂.本综述总结了冷等离子体制备金属催化剂的反应器结构、物理化学机理、获得金属催化剂的结构特性、制备面临的挑战，并对未来发展进行了展望.重点阐述了冷等离子体反应器、制备机制及其对金属催化剂结构和性能的影响.     

Development of Surface Nano-Crystallization in Alloys by Surface Mechanical Attrition Treatment (SMAT)

Nanometer-sized grain structures that exhibit a large number of grain boundaries on the surface of a bulk material demonstrate excellent properties relative to their coarse-grained (CG) equivalents. Surface modification using surface mechanical attrition treatment (SMAT) is an option that cab be used to tailor the corrosion, tribological, mechanical, and chemical reaction properties of a surface. SMAT is an effective route to create the nanostructured surface layer. The SMAT process has unique advantages compared with the other coating and deposition techniques for surface nanocrystallization. For example, SMAT does not alter the chemical composition of the nanocrystalline surface layer in the matrix. In addition, SMAT has been demonstrated to activate the material surface layer by surface modification and enhance the atomic diffusivity. This article presents a review of the advantages offered by the SMAT technique for the creation of high performance surface layers. The influence of the created nanocrystalline layer on mechanical, physical, and chemical properties is assessed. Developments and the current status of the surface nanolayer that are formed are evaluated from a physical approach. Finally, prospects for the future development of grain refinement on the surface of a material matrix and potential applications are presented.