典型醇类物质超临界水氧化反应途径研究

采用自主设计的连续流动气封壁超临界水氧化反应装置,研究了典型醇类物质甲醇、乙醇和异丙醇在超临界水中氧化的反应途径,并归纳了醇类物质超临界水氧化反应的规律及特点。研究结果表明,甲醇超临界水氧化反应的主要中间产物为甲醛,同样条件下转化率较乙醇和异丙醇低;乙醇和异丙醇超临界水氧化反应的主要中间产物为丙酮、乙酸、乙醛和甲醇等。三种醇超临界水氧化过程中均涉及到大量活性自由基的相互作用,表现为脱氢、裂解和聚合等反应形式;产物包括碳链增长、不变、降低三种类型。总体来看,醇类物质超临界水氧化反应的趋势是向碳链降低的方向进行,即通过一系列中间产物最后生成CO₂和水。     

典型醇类物质超临界水氧化反应途径研究

采用自主设计的连续流动气封壁超临界水氧化反应装置,研究了典型醇类物质甲醇、乙醇和异丙醇在超临界水中氧化的反应途径,并归纳了醇类物质超临界水氧化反应的规律及特点。研究结果表明,甲醇超临界水氧化反应的主要中间产物为甲醛,同样条件下转化率较乙醇和异丙醇低;乙醇和异丙醇超临界水氧化反应的主要中间产物为丙酮、乙酸、乙醛和甲醇等。三种醇超临界水氧化过程中均涉及到大量活性自由基的相互作用,表现为脱氢、裂解和聚合等反应形式;产物包括碳链增长、不变、降低三种类型。总体来看,醇类物质超临界水氧化反应的趋势是向碳链降低的方向进行,即通过一系列中间产物最后生成CO2和水。     

碱性介质中甲醇氧化红外光谱电化学循环伏吸研究

本文利用红外光谱电化学循环伏吸法,对碱性体系下甲醇在Pt电极上的氧化过程的中间产物进行分析和研究。结果表明,碱性体系中,CH3OH在Pt电极上具有较好的电化学活性,存在和在酸性体系中不同的反应机理。利用现场红外差谱对氧化过程的产物进行分析,对生成的产物进行指认,并未发现毒化中间产物COL的生成。运用红外光谱电化学循环伏吸及导数伏吸法,对生成的中间体的生成过程进行分析和指认,结果表明:CH3OH的氧化中间产物为HCOO-,在碱性体系下,会继续转化为CO2,CO32-和HCO3-。     

原子转移自由基聚合引发体系的最新研究

本文介绍了关于原子转移自由基聚合(ATRP)引发-活化-失活过程的最新研究情况,包括RATRP、SR&NI ATRP、AGET ATRP、ARGET ATRP以及ICAR ATRP等新型ATRP引发体系.这些新型ATRP体系克服了通常ATRP体系的缺点,比如低价态过渡金属催化剂容易氧化和用量过大的问题,而采用高价态过渡金属催化剂,并极大降低了其用量.尤其是后两种体系仅需微量(1-50ppm)、价态稳定的过渡金属络合物控制聚合反应的进行,使其成为一种适合于工业化生产的活性可控聚合技术.本文同时介绍了杂化及双金属ATRP催化体系,这两种新型催化体系具有较高的催化活性和对聚合反应的调控能力,且通过简单地过滤或沉降就可从聚合产物中脱除.     

Pt/MO2/CNTs催化剂上乙醇电氧化研究

应用循环伏安法研究了几种催化剂Pt/MO2/CNTs（M = Sn, Ti, Ce）和Pt/CNTs对乙醇在H2SO4溶液中的电催化氧化过程。结果表明,金属氧化物的加入有利于乙醇的电氧化,其中,Pt/CeO2/CNTs对乙醇电氧化中间态产物具有显著的氧化性能。综合初始氧化电位、峰电流、总氧化峰面积等参数可以得出Pt/SnO2/CNTs催化剂性能最佳。     

TiCl_4共引发异丁烯正离子聚合合成反应活性聚异丁烯

由H2O/TiCl4/甲醇或乙醚体系引发异丁烯在二氯甲烷与己烷混合溶剂中进行正离子聚合,探讨甲醇用量、聚合时间等因素对正离子聚合以及产物分子量、分子量分布和末端基结构的影响,并在此基础上探讨TiCl4共引发混合C4馏分中异丁烯选择性正离子聚合以制备活性聚异丁烯的可行性.结果表明,含氧试剂对聚合反应起到明显的调节作用,可适当稳定碳正离子活性中心,降低链增长速率,降低聚合产物的分子量(Mn=1600~4600),使分子量分布明显变窄(Mw/Mn=1.35~2.05),并可调节大分子链末端基结构及其含量.降低聚合体系中微量单体浓度以及适当延长聚合反应时间,均有利于提高聚异丁烯大分子链末端α-双键结构含量.通过TiCl4共引发异丁烯正离子聚合制备出末端α-双键含量可以达到70%以上的低分子量高反应活性聚异丁烯.此外,该引发体系还可引发混合C4馏分原料中异丁烯进行高选择性正离子聚合,得到Mn=2000、Mw/Mn=2.59、端基α-双键含量为38.9%的聚异丁烯.     

Pt/MO2/CNTs（M=Sn,Ti,Ce）催化剂上乙醇电氧化研究

应用循环伏安法研究了几种催化剂Pt/MO2/CNTs(M=Sn,Ti,Ce)和Pt/CNTs对乙醇在H2SO4溶液中的电催化氧化过程.结果表明,金属氧化物的加入有利于乙醇的电氧化.其中,Pt/CeO2/CNTs对乙醇电氧化中间态产物具有显著的氧化性能.综合初始氧化电位、峰电流和总氧化峰面积等参数,可以得出Pt/SnO2/CNTs催化剂性能最佳.     

活性炭担载的铂催化剂在碱性条件下选择性氧化甘油制备乳酸（英文）

生物柴油是一种环境友好的燃料,随着其生产及应用的快速增长,其生产过程中重要的副产物甘油将会大量过剩.因此,将甘油转化为高附加值的化学品对于提高生物柴油整体竞争力具有重大意义.乳酸是重要的化工原料,可用于制备生物兼容和可降解的聚乳酸塑料,广泛应用于食品和医药等领域.近年来,由甘油制乳酸的研究受到格外关注,相对于水热反应和氢解反应等,催化选择氧化反应因温和的反应条件而更具竞争力.目前,甘油催化选择氧化制乳酸一般需加入较高比例的NaOH,而碱的类型对反应性能的影响鲜有报道.另外,催化剂常采用TiO_2和CeO_2等氧化物载体,而炭载体具有比表面积较大、在酸碱溶液中稳定及贵金属易于回收等优点,在催化领域有着广泛应用.因此,本文研究了活性炭(AC)担载的Pt催化剂在甘油催化选择氧化制乳酸反应中的催化性能.首先研究了Pt/AC催化剂和碱在甘油催化选择氧化制乳酸过程中的催化作用.实验发现,Pt/AC和碱协同作用才能得到乳酸.Pt/AC催化剂在甘油脱氢生成中间产物(甘油醛和二羟基丙酮)的过程中起主导作用,碱的存在能够促进甘油羟基脱氢;中间产物实验证实,中间产物生成乳酸过程中碱起主导作用,它促进甘油醛和二羟基丙酮脱水反应和坎尼扎罗重排反应获得乳酸.进一步研究发现,中间产物二羟基丙酮比甘油醛更有利于乳酸生成,而Pt/AC催化剂有利于中间产物氧化为甘油酸.进一步研究了不同类型的碱对反应性能的影响.结果表明,碱金属氢氧化物(LiOH,NaOH,KOH)比碱土金属氢氧化物(Ba(OH)_2)更有利于提高甘油转化率和乳酸选择性.在加入碱金属氢氧化物条件下,甘油转化率与其离子半径呈正相关,而乳酸选择性则呈相反趋势.在LiOH存在下,乳酸选择性明显高于NaOH和KOH条件.当LiOH:甘油摩尔比为1.5时,甘油转化率和乳酸选择性均最高.在较低的LiOH与甘油摩尔比时,随着反应的消耗,溶液中的OH–减少,其促进甘油脱氢的作用变弱,并且不利于中间产物进行坎尼扎罗反应,故反应活性和乳酸选择性较差;而当LiOH比例过高时,会导致溶解氧浓度迅速降低,从而使甘油转化率和乳酸选择性下降,同时副产物甘油酸的选择性有所提高.这可能是因为较高比例的碱会促进中间产物甘油醛生成,该中间产物在Pt/AC催化作用下发生进一步氧化反应生成甘油酸.研究了反应时间对催化性能的影响.结果表明,反应6 h后,甘油已经完全转化,乳酸选择性最高,达到69.3%;进一步延长反应时间,乳酸选择性有所下降,而副产物乙酸选择性略有增加,这可能是部分乳酸分解所致.Pt/AC催化剂经5次循环使用后仍保持了较高的甘油转化率和乳酸选择性     

焦化含酚废水深度处理过程中间产物对苯二酚的测定

对苯二酚是含酚废水深度氧化降解过程中的中间产物之一[1,2],为了掌握酚氧化降解过程的变化规律及其氧化动力学的规律,建立一种快速、准确的中间产物分析方法是非常重要的。对于酚在深度氧化降解过程中生成微量的、且处于混合体系中的对苯二酚的分析测试,目前除用高效液相色谱外[3,4],尚未见其它测试方法的报道。虽然通过GC,LGC等精密分析仪器能实现混合物中多组分的同时测定,但设备价格昂贵,难以在环境监测中普遍推广。因此,本文针对酚深度氧化降解过程中生成的微量降解中间产物--对苯二酚,提出了应用分光光度分析法,并对其测试条件及影响因素进行了探讨。此法的特点是在混合液中不必事先进行分离即可直接进行测定。这对于含酚废水在氧化降解过程中的监测和控制有重要意义。     

盐介质环境对苯胺聚合、产物结构及导电性能的影响

本文研究了苯胺在室温下,以H_2O_2/HCl为氧化体系的聚合过程,深入探讨了不同盐(Na Cl、Cu Cl_2、Ni Cl_2、Fe SO_4、Cu SO_4)介质环境对苯胺聚合速率及产率的影响,并对产物的结构及性能进行了分析表征.结果发现, Na Cl对苯胺聚合具有很好的催化作用,过渡金属Cu~(2+)和Fe~(2+)对苯胺聚合速率提高更显著;在室温下, Cu Cl_2可使苯胺聚合产率达到95%以上,在盐介质影响下,苯胺聚合产物从纤维状转变为短棒状,或以珊瑚状纳米结构及球形粒子出现; Na~+、Cu~(2+)和Ni~(2+)介质环境有利于聚苯胺的掺杂,使其具有一定的导电性, Fe~(2+)介质中产生的芬顿反应降低了苯胺聚合产物的掺杂程度,所制聚苯胺为无定型结构,且主要为还原态,不导电.     

Features of Reactions of Radical (Co)Polymerization of Methacryloylguanidine Trifluoroacetate in Various Solvents

A method for the synthesis of methacryloylguanidine trifluoroacetate was developed for the first time and its radical (co)polymerization was carried out in various solvents. The polymerization proceeds homogeneously in water, methanol, and DMSO up to high conversion and heterogeneously in acetone after reaching 20% conversion. For the first time, methacryloylguanidine trifluoroacetate and methylmethacrylate copolymers were synthesized in acetone and DMSO; the copolymerization constants for this system in acetone were determined to be r₁ = 1.41 ± 0.24 and r₂ = 0.11 ± 0.01. Preliminary biological tests showed a fairly high biocidal and fungicidal activity of the synthesized copolymers.     

Electrical field influence on molecular mass and electrical conductivity of polyaniline

We have described the primary studies on the conductivity and molecular weight of polyaniline in an electric field as it is used in a field effect experimental configuration. We report further studies on doped in-situ deposited polyaniline. First we have chemically synthesized polyaniline by ammonium peroxodisulfate in an acidic solution, with aqueous, organic and emulsion conditions at different times. Next, we measured mass and conductivity and obtained the best time of polymerizations. Then, we repeated these reactions under different electrical fields in constant time and measured mass and conductivity. The polyaniline is characterized by gel permeation chromatography (GPC), UV-visible spectroscopy and electrical conductivity. Polyanilines with high molecular weight are synthesized under electric field M _w = (5.2–6.8) × 10⁵, with M _w/M _n = 2.0–2.5. The UV-visible spectra of polyanilines oxidized by ammonium peroxodisulfate and protonated with dodecylbenzenesulfonic acid (PANi-DBSA), in N-methylpyrolidone (NMP) show a smeared polaron peak shifted into the visible. Electrical conductivity of polyaniline has been studied by four-probe method. The conductivity of the films of emeraldine protonated by DBSA cast from NMP is higher than 500 S/cm under (10 kV/cm² of potential) electric field and shows an enhanced resistance to ageing. Next, we carried chemical polymerization at the best electric field at different times. Finally, the best time and amount of electric field were determined. Polymers synthesized under an electric field probably have better physical properties regarding the existence of less branching and high electric conductivity.     

Template Synthesis of Polyaniline in the Presence of Poly-(2-acrylamido-2-methyl-1-propanesulfonic Acid)

A template oxidative polymerization of aniline in aqueous solutions containing poly-(2-acrylamido-2-methyl-1-propanesulfonic acid) and ammonium persulfate yields a polyaniline complex with the polyacid soluble in water. According to the data of spectral measurements, the process of polymerization is of a pronounced autocatalytic nature. The consequences of this are both the formation of a nonuniform distribution of oxidized and nonoxidized fragments of the polymer chain and the formation of a macroscopic scale of redox nonuniformities in the reaction volume during the process of polymerization. The spectra of absorption of the polyaniline/polyacid films on transparent glass electrodes with a conductive layer of SnO₂ and the data of potentiodynamic measurements in the potential region 0–1.0 V (Ag/AgCl) are typical for polyaniline with moderate electroconduction.     

Nanocomposites Produced by Direct Intercalation of Secondary Doped Polyaniline in V2O5

The possibility of the production of nanocomposites based on V₂O₅ and conducting polymers by direct intercalation of macromolecules of secondary doped polyaniline into the interlayer galleries of nanoparticles of aqueous V₂O₅ sol was demonstrated for the first time. The driving force of the intercalation process is substitution of the protons present in the galleries of the V₂O₅ by a polyaniline chain carrying a positive charge.     

Synthesis,Characterization and Electrochemical Behavior of p-NiO/n-TiO2/Polyaniline Composites

The p-NiO/n-TiO2/polyaniline composites were synthesized via in situ polymerization of aniline. The structure and morphology of the composites were characterized by means of X-ray diffraction(XRD), scanning electron microscopy(SEM), Fourier transform infrared spectroscopy(FTIR) and UV-Vis absorption spectroscopy. It was found that the p-n junction p-NiO/n-TiO2 particles were trapped in the polyaniline molecular matrix and the polyaniline was deposited on the surface of the particles to form a kind of flower cluster morphologies. The electrochemical behavior of the polyaniline composites was investigated. The electrochemical reactivity of the polyaniline was influenced by the p-NiO/n-TiO2 particles due to the effect of electron-hole pairs in these p-n junction particles. The reversibility of redox process and current intensity of the polyaniline composites with the changing of potential scan rate were also discussed.     

Conductive composite of polyaniline and tungsten carbide

Conductive polyaniline/tungsten carbide (PANI/TC) composite was synthesized via polymerization of the aniline monomer by (NH₄)₂S₂O₈/H₂SO₄ oxidant system in the presence of an aqueous suspension of TC. The structure, thermal stability and conductivity of PANI/TC composite were studied and the results were also compared with the pure PANI. The results showed that there was a strong interaction between the TC particles and PANI molecular chains. The crystalline structure of TC remained undisturbed upon with interaction with PANI chains. The thermal stability of PANI/TC composite was better than that of pure PANI. The direct current conductivity values of PANI/TC composite decreased slowly as the temperature increased from 25 to 165°C and PANI/TC composite exhibited significantly higher conductivity than the pure PANI.     

苯胺乳液聚合条件的研究

以（ＮＨ４）２Ｓ２Ｏ８为氧化剂、在非极性溶剂－功能质子酸－水三相体系中,采用乳液聚合方法合成聚苯胺乳液和粉末。对乳液聚合与化学氧化溶液聚合合成的聚苯胺性能进行了比较,研究了掺杂酸、氧化剂、反应时间、温度和水相浓度等聚合条件对聚苯胺导电性、溶解性、乳液粘度等性能的影响。结果表明,乳液聚合产率大于８０％,聚苯胺电导率大于１Ｓ／ｃｍ,在有机溶剂中的溶解性与用化学氧化合成的聚苯胺相比有明显提高。     

Microtubules of polyaniline doped with HCl and HBF4

Microtubules of polyaniline (PANI) doped with HCl, HBF₄, and β-naphthalene sulfonic acid (NSA) were synthesized by an improved in situ doping polymerization method. Ultraviolet-visible spectra, scanning electron microscopy, ESR, and X-ray diffraction characterized the molecular structure of the resulting PANI microtubules. These microtubules had a diameter of 1 ∼ 10 μm and a conductivity at room temperature of 0.2 ∼ 3.5 S/cm, depending on the molecular structure and concentration of the dopant. The degree of crystallinity of the PANI microtubules was enhanced by increasing the molecular size of the dopant; that is, the order PANI-NSA > PANI-HBF₄ > PANI-HCl was observed in the crystallinity of the microtubules. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 4605–4609, 1999     

Preparation of 3D MnO2/Polyaniline/Graphene Hybrid Material via Interfacial Polymerization as High‐Performance Supercapacitor Electrode

MnO₂/polyaniline/graphene composite as a supercapacitor electrode material was synthesized through an interfacial polymerization approach in the interface of oil/water phase. The as‐synthesized MPG is characterized by infrared spectroscopy, XRD, XPS, SEM and TEM, and its electrochemical performance is measured by cyclic voltammetry, galvanostatic charge/discharge, and electrochemical impedance spectroscopy. The 3D nanostructure of MPG and loose nanorod structure of polyaniline (PANI) coated with round MnO₂ pellets could be clearly observed. The maximum energy density of MPG is 45.4 Wh/kg (at a power density of 67.8 kW/kg) and the highest power density is 229.2 kW/kg (at an energy density of 25.7 Wh/kg). The capacitance retentions after 500 cycles at the scan rate of 5 mV/s for MGP composite and PANI/graphene are 70.4% and 59.1%, respectively, and the capacitance values after 500 cycles are 158.4 F/g and 114.8 F/g, respectively. The improved performance of MPG is due to the 3D nanostructure, loose nanorod structure of PANI and stable support of graphene, which prevent the mechanical deformation effectively during the fast charge/discharge process and facilitate the diffusion of the electrolyte ions into the inner region of active materials. The composite material is very promising for the next generation of high‐performance supercapacitors electrode.     

Synthesis of conducting polyaniline using novel anionic Gemini surfactant as micellar stabilizer

The Gemini surfactant 9B-4-9B containing sodium sulfonate as hydrophilic head group was synthesized based on nonylphenol and characterized by FTIR, ¹H NMR spectroscopy and the surface tension measurement. The CMC and C₂₀ of the 9B-4-9B were smaller than that of sodium dodecylbenzene sulfonate and sodium dodecylsulfate, respectively, indicating excellent efficiency of micelle formation and reduced surface tension. Conducting polyaniline salts were synthesized by chemical oxidative micellar polymerization of aniline in water firstly using Gemini surfactant 9B-4-9B as the micelle stabilizer and ammonium peroxydisulfate as the oxidant at 0 °C. The stable polyaniline dispersions have been obtained when the molar ratio of the 9B-4-9B to aniline was equal to or above 0.5 used in the polymerization system. The obtained granular polyaniline particles with the size of 1-2 μm were characterized by FTIR, UV-Vis, SEM, WAXD and conductivity measurement.