Keggin离子改性凹凸棒土去除水溶液中Zn（Ⅱ）的研究

为探究Keggin离子改性凹凸棒土用于去除水溶液中Zn(Ⅱ),采用XRD、SEM、AFM、TG和XPS技术对改性土进行表征,并利用等温吸附、动力学及热力学方程对其吸附机制进行研究。结果显示,改性土于2θ为13.7°、19.9°和27.6°对应衍射面为(200)、(040)和(400)处出现了凹凸棒土的特征衍射峰。SEM分析显示其形貌为棒晶及棒晶束之间形成的聚集体。AFM表征显示该材料表面粗糙度为32.3nm。热重分析表明改性土表面仅有少量有机物。XPS谱图分析显示Zn(Ⅱ)已成功被吸附到改性土表面上,该过程并未发生氧化还原反应。改性凹凸棒土吸附水溶液中Zn(Ⅱ)是一个自发、吸热及熵驱动的过程。采用Keggin离子改性凹凸棒土制成的廉价吸附剂可用于去除水溶液中Zn(Ⅱ)。

Keggin离子改性凹凸棒石对废水中六价铬的吸附研究

在溶液pH为4￣9时,Keggin离子改性凹凸棒石的ζ电位为正值,对水溶液中CrO42-、HCrO4-的吸附性能良好。吸附类型属于Langmuir型单分子层吸附,单分子层饱和吸附量为3.59mg/g。XRD分析结果表明,Keggin离子不会引起凹凸棒石结构的明显改变。

Dehydrocyclization of n-Hexane over Heteropolyoxometalates Catalysts

The catalytic dehydrocyclization of n-hexane was studied here for the first time using a number of compounds based on H3PMo12O40. The described catalysts were prepared by either replacing the acidic proton with counter-ions such as ammonium or transition metal cations (NH4+, Fe3+, K+), or by replacing Mo6+ with (Ni3+, Co3+, Mn3+) in the polyoxometalate framework, as reported earlier. For comparison purposes, the known (TBA)7PW11O39 catalyst system was used. All reactions were conducted at different temperatures in the range 200 - 450. The Keggin structure of these heteropolycompounds was ascertained by XRD, UV and IR measurements. 31P NMR measurements and thermal behaviour of the prepared catalysts were also studied. These modified polyoxometalates exhibited heterogeneous superacidic catalytic activities in dehydrocyclization of n-hexane into benzene, cyclohexane, cyclohexene and cyclohexadiene. The catalysts obtained by substituting the acidic proton or coordination atom exhibited higher selectivity and stability than the parent compound H3PMo12O40. Catalytic activity and selectivity were heavily dependent on the composition of the catalyst and on the reaction conditions. At higher temperatures, the catalyst exhibited higher conversion efficiency at the expense of selectivity. Using higher temperatures (>400) in the presence of hydrogen carrier gas, selectivity towards dehydrocyclization ceased and methane dominated. To explain the results, a plausible mechanism is presented, based on super-acidic nature of the catalyst systems.

A kinetic study of the electron-transfer in the reaction of tribenzylchlorotin with[CoW_(12)O_(40)]^(5-)

A kinetic study of the electron-transfer in the reaction of tribenzylchlorotin with potassium 12-tungsto cobalt （Ⅲ） ate ion, Ks[CoW12O40], abbreviated as Co（III）W, has been performed in different solvents. The studies were carried out in methanol, ethanol, acetonitrile and acetic acid/water. The rate constants, reaction rates and activation parameters were calculated. Our findings show that the rate of disappearance of the Co（Ⅲ） is pseudo-first order. The kinetic data is strongly affected by used solvents. The maximum and minimum rate constants were achieved in the ethanol and acetic acid/water （70/30） as a solvent, respectively. In all of the used solvents, negative value of activation entropies was observed, but negative activation enthalpies are observed in methanol, ethanol and acetonitrile. The reaction rate is increased with increase of Co（Ⅲ） concentration. ？2009 Fatemeh E Bamoharram. Published by Elsevier B.V. on behalf of Chinese Chemical Society. All rights reserved.

柱撑蒙脱石制备与表征

本文采用多种方法制备keggin离子，并探索出制备稳定keggin离子的适宜酸碱度，用此柱化剂制备出层间距为2．4～2．5nm的柱撑蒙脱石。应用X射线走向衍射技术、红外光谱、差热分析对往撑蒙脱石进行表征，用BET、吡啶吸附考察了其表面物理化学性质。结果表明，用Keggin离子制备出的柱撑蒙脱石其层间距在自然状态下为2．4～2．5nm，350C灼烧，层间距稳℃定在1．8nm，且具有耐热性能好、较大的比表面积和较强的Lewis酸位中心等特点．

柱撑粘土矿物的研究新进展──新矿物材料研究综述之一

柱撑粘土矿物作为一种大层间距的多酸型层柱微孔材料，是一种性能优异的催化剂和吸附剂。本文在较全面分析前人资料的基础上，结合笔者所做的工作，对柱撑粘土矿物的制备、性能表征及其应用最新研究进展进行综述与展望。

分光光度法测定微量铂(Ⅳ)的高灵敏显色反应及其应用研究

研究了２－（３，５－二氯－２－吡啶偶氮）－５－二甲氨基苯胺（３，５－ｄｉＣｌ－ＰＡＤＭＡ）光度法测定铂（Ⅳ）的最佳条件．结果表明，在ｐＨ３．２５～５．２５的ＨＡｃ－ＮａＡｃ缓冲介质中，铂与试剂在沸水浴中加热２５ｍｉｎ后能形成稳定的蓝色配合物，加入无机酸及乙醇后转变为绿蓝色，其最大吸收波长位于６３４ｎｍ，表观摩尔吸光系数高达１．０４×１０５Ｌ·ｍｏｌ－１·ｃｍ－１．以ＥＤＴＡ为掩蔽剂，较大量的常见金属离子不干扰测定．铂含量在０～１２μｇ／１０ｍＬ范围内符合比尔定律．方法已应用于催化剂中微量铂（Ⅳ）的测定．

氧化铝柱层状镧钛酸盐的制备

本文采用分步交换法首次制得了一种新的层柱材料—氧化铝柱层状镧钛酸盐．应用Ｘ射线衍射（ＸＲＤ）、红外光谱（ＩＲ）及透射电子显微镜（ＴＥＭ）等方法对该新材料进行了表征．结果表明，此材料具有较大的层间距（ｄ＝２．０５ｎｍ，６００℃）和较高的热稳定性（７００℃）．同时，考察了合成条件的改变对该材料性能的影响．

氧化铝柱层状磷酸锡的制备和表征

采用分步交换法制备铝Keggin离子柱层状磷酸锡。产物经 5 0 0℃焙烧处理 ,得到层间距为 1 35nm的氧化铝柱层状材料 (比母体α SnP的层间距高出 0 5 7nm) ,而且Al7+ 13 柱化程度大大优于直接法合成的产物。比较了不同柱化方法的柱化效果 ,以有机胺水解AlCl3 制备的含铝Keggin离子柱化剂的柱化效果明显好于无机碱水解体系。XRD ,IR ,TG DTA等分析结果证实有机胺在铝Keggin离子柱化过程中起重要作用。

BP-PSO优化改性凹凸棒土吸附Pb(Ⅱ)条件及其机制研究

为探究Keggin离子改性凹凸棒土对Pb(Ⅱ)的吸附性能及获得Pb(Ⅱ)最大去除率,采用响应面(RSM)及反向传播神经网络结合粒子群算法(BP-PSO)对去除条件进行优化,利用X射线光电子能谱仪表征、动力学、等温吸附及热力学研究对吸附机理进行探讨,采用可渗透反应墙对Pb(Ⅱ)去除进行动态模拟。XPS表征结果显示Pb(Ⅱ)被吸附到改性土表面,该吸附过程并未发现氧化还原反应。RSM优化下,预测和实际Pb(Ⅱ)最大去除率分别为83. 85%和81. 24%,相对应的去除条件:反应时间为50. 02 min、初始Pb(Ⅱ)浓度为150 mg/L、温度为20℃及初始p H值为7。BP-PSO优化下最大去除率为85. 68%,对应的实验条件:温度为20℃,反应时间为52. 28 min,初始Pb(Ⅱ)浓度为250 mg/L,初始p H值为7,在此条件下验证实验值为84. 41%。BP-PSO更合适用于优化改性凹凸棒土吸附水溶液中Pb(Ⅱ)。改性凹凸棒土对Pb(Ⅱ)的吸附为吸热、自发及熵驱动的过程。可渗透反应墙中对Pb(Ⅱ)去除率的去除效果不理想。

无机柱撑蒙脱石的柱化机理及应用研究进展

柱撑蒙脱石作为一种新型的多孔材料是当前矿物材料学研究的热点之一,其具有大的比表面积、大小可调的孔径、强的酸性而成为性能优异的吸附剂和催化剂,在石油化工和环保领域具有广阔的应用前景.本文概述了柱撑蒙脱石的制备、柱化机理及其应用等方面的研究进展,指出了柱撑蒙脱石研究中存在的问题(热稳定性,水热稳定性和孔结构等),报道了柱撑蒙脱石研究热点,论述了柱撑蒙脱石研究的发展方向.

柱撑蒙脱石的制备研究

以山西某地膨润土为原料、Keggin离子作柱化剂,制备了柱撑蒙脱石,探讨了浆固含量、柱化剂用量、反应温度、反应时长和pH等因素的影响。将柱撑蒙脱石经过不同温度下煅烧,探讨了其热稳定性。结果表明,蒙脱石柱撑后层间距可增大至2.007nm,柱化剂用量增大和加酸活化控制适宜pH有利于柱撑效果。柱撑蒙脱石在500℃煅烧后晶体层状结构保持完好。

镍的磷钨酸盐在苯甲醛合成中的催化性能研究

以过渡金属离子(Ni2+)取代的Keggin型磷钨酸为相转移催化剂,在无溶剂条件下,苯甲醇经催化氧化合成了苯甲醛。考察了催化剂的种类和用量、反应温度、反应时间和H2O2用量对苯甲醇氧化反应的影响。实验结果证明,Ni取代的Keggin型磷钨酸[CTA]10[(PW11Ni O39)2O]是苯甲醇制苯甲醛的高效催化剂。适宜的反应条件为:0.2g催化剂,90℃反应4h,苯甲醇的产率为91.51%,选择性为94.6%,转化率为96.73%。

Synthesis and Crystal Structure of a Novel 1D Chain-like Organic Inorganic Hybrid Rare Earth Derivative of Polyoxometalate: H_(0.5)[Sm(H_2O)_6]_(0.25)[Sm(H_2O)_5]_(0.25){[Sm(H_2O)_7][Sm(H_2O)_2-(DMSO)][SiW_(11)O_(39)]}·4.5H_2O

A 1D chain-like organic-inorganic hybrid rare earth derivative of polyoxometalate H0.5[Sm（H2O）6]0.25[Sm（H2O）5]0.25{[Sm（H2O）7][Sm（H2O）2（DMSO）][SiW11O39]}·4.5H2O has been firstly synthesized by reaction of α-K8SiW11O39.13H2O, HClO4, Sm2O3 with dimethyl sulfoxide （DMSO） and characterized by elemental analysis, IR spectra and single crystal X-ray diffraction. The neighboring polyanionic units {[Sm（H2O）7][Sm（H2O）2（DMSO）][SiWHO39]}^2- are bridged together to a 1D chain structure by means of [Sm（H2O）2（DMSO）]^3＋ ion.