沸石分子筛及其负载型催化剂去除VOCs研究进展

挥发性有机物（VOCs）的排放对自然环境、人类健康产生了严重危害,吸附法和催化氧化法是治理VOCs的有效方法.沸石分子筛含有丰富的微孔,比表面积大,且含有较多的酸位点,具有一定的催化活性,十分适合作为催化剂载体材料,被广泛应用于分离、吸附及催化等领域.本文综述了不同沸石分子筛吸附去除及沸石基负载型催化剂催化氧化去除烷烃、芳香烃、醛类、酮类、酸类、酯类、醇类及氯代烃等VOCs的研究进展.分析表明,沸石吸附剂的孔道结构、硅铝比、表面物理化学性质,VOCs种类、极性、亲水性,对沸石分子筛吸附性能影响较大;沸石载体表面酸碱度,催化剂活性组分种类、分散性,VOCs种类等是影响负载型催化剂催化活性的重要因素;沸石载体和活性组分之间存在协同作用,赋予了负载型催化剂优异的催化活性.沸石负载贵金属催化剂对各类VOCs的催化氧化性能优于沸石负载金属氧化物催化剂,但贵金属价格昂贵,成本较高,通过合理设计多组分金属氧化物催化剂,可显著提高负载型催化剂的催化活性.此外,本文对沸石分子筛及其负载型催化剂去除VOCs的未来研究方向进行了展望.     

沸石分子筛材料在消除挥发性有机化合物反应中的吸附与催化性能（英文）

作为空气污染物的主要成分之一,挥发性有机化合物(VOCs)会极大地破坏生态环境并损害人体健康.在众多消除VOCs的方法中,吸附法由于操作简单、成本低廉的优势而在工业上得以广泛应用.催化燃烧法则因去除效率高,适用范围广且无二次污染等优点被认为是VOCs消除最有效的手段之一.目前,活性炭是最常用的VOCs吸附剂,但存在再生困难、抗湿性差、易燃等诸多问题.与活性炭等常规吸附剂相比,沸石分子筛作为VOCs吸附剂其主要优势在于:(1)沸石分子筛的疏水性可调,通过调控分子筛骨架的硅铝比可以调节分子筛的亲疏水性,高硅铝比的沸石分子筛有着优异的疏水性能,从而可以有效降低在一定湿度条件下水对VOCs分子的竞争吸附;(2)均一的孔径分布可以有效地进行分子识别,从而使吸附剂对VOCs的选择性吸附性大大提高;(3)沸石分子筛一般由硅铝构成,本身不可燃且水热稳定性好,因此能够与微波加热等其他手段相结合以降低吸附剂重生能耗,提高操作安全性;(4)沸石分子筛比表面积大,吸附容量高,是作为蜂窝转轮吸附技术中吸附剂的理想材料,而该技术是目前工业大规模消除VOCs的研究热点.因此,沸石分子筛由于其独特的性质,被视为一种简单高效、选择性好的VOCs吸附剂.现阶段,催化燃烧VOCs所使用的催化剂常用金属氧化物作为载体,但是金属氧化物比表面积相对较小且孔道结构不均一,因此严重影响了催化剂对VOCs的催化燃烧效率,限制了催化燃烧活性的提高.而与金属氧化物载体相比,沸石分子筛材料具有均一的孔道结构以及相对较大的比表面积等优点,而将具有较好吸附选择性和吸附容量的沸石分子筛作为载体,负载活性组分后可以实现催化剂催化燃烧性能的显著提高,从而成为VOCs催化燃烧的理想催化剂.本文综述了目前沸石分子筛材料作为吸附剂和催化剂载体的负载型催化剂消除各类VOCs的研究进展.对于沸石分子筛作为VOCs吸附剂,我们小结了影响其吸附容量和吸附选择性的因素,发现分子筛的孔道大小和阳离子类型与VOCs的吸附情况密切相关.在此基础上,进一步简单介绍了分子筛蜂窝吸附转轮技术的研究现状.对于沸石分子筛作为催化剂载体,我们总结了其用于各类VOCs催化燃烧的研究情况,如烷烃类、芳烃类和醛类等.探究了催化性能的影响因素及相应的催化机理,发现分子筛的孔道结构、阳离子类型、硅铝比等都会显著影响沸石分子筛负载型催化剂的催化活性.最后,探讨了沸石分子筛应用于VOCs消除目前所存在的问题,同时展望了该领域未来的研究和发展方向.     

有序多孔过渡金属氧化物及其负载贵金属催化剂对挥发性有机物氧化的催化性能

大部分的挥发性有机物(VOCs)污染环境,危害人身健康.目前,我国虽然已开展了治理 VOCs污染的工作,但还缺乏有效的、拥有自主知识产权的 VOCs治理技术,因此研发新型高效 VOCs处理技术迫在眉睫.催化氧化法是公认的最有效消除 VOCs的途径之一,而高性能催化剂的研发是实现该过程的关键.近年来,人们围绕消除 VOCs的高效且价廉的催化剂的研发开展了卓有成效的工作,许多过渡金属氧化物、混合或复合金属氧化物及其负载贵金属催化剂均被认为是有效的催化氧化材料.与体相材料相比,多孔材料具有发达的孔道结构和高的比表面积,一方面有利于反应物的扩散、吸附和脱附,因而具有更高的催化活性和选择性;另一方面有利于活性组分(如贵金属等)在多孔材料表面的高分散,抑制活性组分的烧结,因而具有更好的催化稳定性.本文简述了近年来多孔金属氧化物在环境污染物消除领域的研究进展,阐述了以有序介孔或大孔过渡金属氧化物、钙钛矿型氧化物和负载贵金属催化剂的制备及其对典型 VOCs(如苯系物、醇类、醛类及酮类等)氧化的催化性能,重点介绍了四类催化材料,包括有序介孔过渡金属氧化物或复合氧化物(Co3O4, MnO2, Fe2O3, Cr2O3和 LaFeO3等)催化剂,有序介孔金属氧化物负载贵金属(Au/Co3O4, Au/MnO2和 Pd/Co3O4等)催化剂,三维有序大孔过渡金属氧化物或复合氧化物(Fe2O3, LaMnO3, La0.6Sr0.4MnO3和 La2CuO4等)催化剂,以及三维有序大孔金属氧化物负载贵金属(Au/Co3O4, Au/LaCoO3, Au/La0.6Sr0.4MnO3和 AuPd/Co3O4等)催化剂的制备及其物化性质与对苯、甲苯、二甲苯、乙醇、丙酮、甲醛、甲烷或氯甲烷等 VOCs氧化的催化性能之间的相关性.借助二氧化硅或聚甲基丙烯酸甲酯微球等硬模板,采用纳米浇铸法可制备出二维或三维的有序单一或多级孔道结构的金属氧化物.研究表明,多孔金属氧化物的催化性能远优于其体相甚至纳米催化剂的.有序多孔材料的优异催化性能与其拥有大的比表面积、高的吸附氧物种浓度、优良的低温还原性、独特的孔道结构、活性组分的高分散以及贵金属与氧化物载体之间的强相互作用等有关.探明影响催化剂活性的因素有利于从原子水平上认识催化过程,为新型高效催化剂的设计与制备奠定基础.本文还指出了此类研究中存在的一些问题,例如利用硬模板法制备多孔材料的缺点是目标催化剂的收率低,硬模板浪费严重,大规模制备多孔催化剂势必增加制备成本,这些问题有待于妥善解决.与此同时,还展望了 VOCs消除技术的未来发展趋势,采用多种技术联用的方法有望最大程度地提高 VOCs的消除效率.     

Fe(Ⅲ)/Y型沸石的表征和催化性能

用ＸＰＳ，Ｍｏｓｓｂａｕｅｒ谱，ＴＰＲ，ＮＨ３－ＴＰＤ，Ｐｙ－ＩＲ和脉冲微反等技术研究了Ｆｅ／Ｙ型沸石中Ｆｅ的表面和体相状态，还原性，酸性及其甲苯转化反应性能。结果表明，Ｆｅ／Ｙ型沸石中Ｆｅ／Ｙ上六配位，八面体的形式存在，且可能形成超细粒子。     

不同制备方法对Cu-ZSM-5沸石分子筛上NO分解反应活性的影响

不同制备方法对Ｃｕ┐ＺＳＭ┐５沸石分子筛上ＮＯ分解反应活性的影响＊韩一帆汪仁（华东理工大学工业催化研究所，上海２００２３７）关键词Ｃｕ－ＺＳＭ－５沸石分子筛，一氧化氮，催化分解，直接粘混法，离子交换法如何减少各类污染源所排放的氮氧化物（ＮＯｘ）对环境...     

酸性沸石分子筛催化Knoevenagel综合反应

在高硅／铝比的酸性沸石分子筛HY上实现了Knoevenagel缩合反应，Bronsted酸和Lewis酸均可催化Knoevenagel缩合反应。考察了羰基化合物和活泼亚甲基化合物的反应活性顺序。结果表明，羰基化合物的羰基极化程度越高，反应越容易进程,示同于碱催化时的Knoevenagel缩合反应，活泼亚甲基化合物的活泼氢的酸性并不是影响其反应活性的重要因素。     

钛酸盐沸石分子筛催化苯酚羟基化反应的研究

采用Ｘ射线粉末物相分析、红外及紫外漫反射光谱，差热分析，ＮＨ３－脱附法和气体吸附等测试手段研究了Ｔｉ－Ｓｉ沸石ＴＳ－１，ＴＳ－２，Ｔｉ－ＺＳＭ－４８及钛酸钠、钛铝酸钠和钛酸铜分子筛的性能和结构，利用苯酚羟基化反应证明了含有ＴｉＯ，四配位结构单元的沸石分子筛具有催化氧化活性，考察了各种实验条件对苯酚羟基化反应的影响。     

沸石分子筛吸附和催化降解亚硝胺

综述了近年来国内外在使用沸石和介孔分子筛吸附和催化分解以及检测亚硝胺方面的新进展.亚硝胺属于强致癌物,是吸烟导致癌症的重要原因.本文剖析了沸石对亚硝胺的选择性吸附以及大体积亚硝胺在小微孔沸石上的"嵌入式"吸附模式,探讨了沸石在气相和液相中吸附挥发性亚硝胺的规律和影响因素;研究了介孔分子筛材料对于催化降解烟草特有亚硝胺的高活性,阐述了修饰金属氧化物对于提高沸石吸附或催化分解亚硝胺能力的促进作用,并展望消除亚硝胺污染功能新材料的发展方向.     

硅铁ZSM-48沸石的CO加氢催化性能

考察了硅铁ＺＳＭ－４８负载铁、钾催化剂在ＣＯ加氢制备低碳烯烃反应中的催化性能。结果表明,Ｆｅ（Ⅲ）离子同晶取代Ｓi（Ⅳ）后,不仅使沸石分子筛的表面能量分布更加趋 于均匀,而且明显促进了活性组分铁的还原和减弱了催化剂表面吸附氢的能力,从而大大提高了反应活性和选择性。硅铁ＺＳＭ－４８负载过量的铁、钾都不利于ＣＯ加氢合成低碳烯烃,其负载量的量侍值分别为８％和１．９％。另外,硅铁ＺＳＭ－４８的焙烧温度和焙烧     

Combustion of volatile organic compounds over mixed-regime catalytic membranes

Catalytic membranes operating in a mixed permeation regime (i.e., with significant Knudsen and laminar contributions) have been developed. The membranes prepared had wide pores and presented a low pressure drop. After the addition of γ-Al₂O₃ and Pt, the resulting catalytic membranes were active for the combustion of VOCs. Their performance was compared with that of similar catalytic membranes operating under the Knudsen diffusion regime.     

Sampling and analysis of volatile organic compounds in bovine breath by solid-phase microextraction and gas chromatography-mass spectrometry

A relatively noninvasive method consisting of a face mask sampling device, solid-phase microextraction (SPME) fibers, and a gas chromatography-mass spectrometry (GC-MS) for the identification of volatile organic compounds (VOCs) in bovine breath was developed. Breath of three morbid steers with respiratory tract infections and three healthy steers were sampled seven times in 19 days for 15 min at each sampling. The breath VOCs adsorbed on the divinylbenzene (DVB)-Carboxen-polydimethyl siloxane (PDMS) 50/30 microm SPME fibers were transported to a laboratory GC-MS system for separation and identification with an in-house spectral library of standard chemicals. A total of 21 VOCs were detected, many of them for the first time in cattle breath. Statistical analyses using Chi-square test on the frequency of detection of each VOC in each group was performed. The presence of acetaldehyde (P < or = 0.05) and decanal (P < or = 0.10) were associated more with clinically morbid steers while methyl acetate, heptane, octanal, 2,3-butadione, hexanoic acid, and phenol were associated with healthy steers at P < or = 0.10. The results suggest that noninvasive heath screening using breath analyses could become a useful diagnostic tool for animals and humans.     

乙酸乙酯在Al2O3-Ce0.5Zr0.5O2负载的金属氧化物催化剂上的催化燃烧

制备了Fe, Co, Cu, Cr和Mn金属氧化物催化剂, 所用载体为Al2O3-Ce0.5Zr0.5O2复合氧化物. 利用X射线衍射(XRD), 程序升温还原(TPR), 储氧量测试, BET比表面测试和光电子能谱(XPS)表征了催化剂. 并利用活性测试表征了各种催化剂对乙酸乙酯催化燃烧能力. 各种表征结果证实, 由于催化剂Mn/Al2O3-Ce0.5Zr0.5O2(1:2, 质量比)具有最多的可还原物种, Cu/Al2O3-Ce0.5Zr0.5O2(1:2)具有较多的可还原物种和最强的可还原能力, 使它们对乙酸乙酯催化燃烧表现出了最好的活性. 在催化剂Cu/Al2O3-Ce0.5Zr0.5O2(1:2)和Mn/Al2O3-Ce0.5Zr0.5O2(1:2)上, 乙酸乙酯于245 ℃转化了99%, 表明这两种催化剂具有广泛的应用潜力.     

Detection of volatile organic compounds by temperature-programmed desorption combined with mass spectrometry and Fourier transform infrared spectroscopy

A temperature-programmed desorption (TPD) device connected to a mass spectrometer was used to detect volatile organic compounds from air samples. The main aim was to develop an analytical method, by which both non-polar and polar organic components can be detected in the same run. In TPD, the adsorbed compounds are desorbed from the resin more slowly than in the conventional trapping techniques, such as purge-and-trap technique, in which the resin is flash-heated and the compounds are desorbed at the same time to a cryogenic trap or an analytical column. In TPD, the adsorbent resin acts also as an analytical column. In this way it is possible to obtain more rapid analysis, and also a more simple instrumentation, which can be used on-line and on-site. In this work, a new version of TPD device, which uses a resistor for heating and a Peltier element for rapid cooling, was designed and constructed. Various adsorbent resins were tested for their adsorption and desorption properties of both polar and non-polar compounds. When using a mixture of adsorbent resins, Tenax TA and HayeSep D, it was possible to analyze both polar, low-molecular weight compounds, such as methanol and ethanol, and non-polar volatile organic compounds, such as benzene and toluene, in the same run within 15 min including sampling. The same TPD principle was also tested using a Fourier transform infrared spectrometer as an analytical instrument, and the results showed that it was possible to obtain a separation of similar compounds, such as hexane and heptane, and still retaining the same sensitivity as the original on-line FTIR instrument.     

Catalytic Combustion of Ethyl Acetate over Al2O3- Ce0.5Zr0.5O2 Supported Metal Oxide Catalysts

The catalysts for the combustion of ethyl acetate were prepared using Fe, Co, Cu, Cr, and Mn metal oxide as active components supported on Al₂O₃-Ce_0.5Zr_0.5O₂ mixed oxides and characterized by X-ray diffraction (XRD), temperature programmed reduction (TPR), oxygen storage capacity measurement, BET surface area, XPS measurement, and activity test. According to the results of characterization, it was found that Cu/Al₂O₃-Ce_0.5Zr_0.5O₂ (1:2, mass ratio) and Mn/Al₂O₃-Ce_0.5Zr_0.5O₂ (1:2) catalysts presented excellent activity for the catalytic combustion of ethyl acetate, because of the more reducible species and high reducibility of the catalysts. For ethyl acetate oxidation, more than 99% conversion was achieved at 245 °C over catalysts Cu/Al₂O₃-Ce_0.5Zr_0.5O₂ (1:2) and Mn/Al₂O₃-Ce_0.5Zr_0.5O₂ (1:2, mass ratio), indicating that the catalysts had great potential for wide use.     

Determination of complex mixtures of volatile organic compounds in ambient air: an overview

This article reviews developments in the sampling and analysis of volatile organic compounds (VOCs) in ambient air since the 1970s, particularly in the field of environmental monitoring. Global monitoring of biogenic and anthropogenic VOC emissions is briefly described. Approaches used for environmental monitoring of VOCs and industrial hygiene VOC exposure assessments are compared. The historical development of the sampling and analytical methods used is discussed, and the relative advantages and disadvantages of sorbent and canister methods are identified. Overall, there is considerable variability in the reliability of VOC estimates and inventories. In general, canister methods provide superior precision and accuracy and are particulary useful for the analysis of complex mixtures of VOCs. Details of canister methods are reviewed in a companion paper. C. C. Austin is an Invited Scientist of the National Research Council of Canada.     

Low-temperature plasma ionization source for the online detection of indoor volatile organic compounds

A simple-structure, low-power, and low-cost low temperature plasma (LTP) ionization source, coupled with mass spectrometry, for the online detection of indoor volatile organic compounds (VOCs) has been constructed in this work. Air, instead of noble gases, was employed as the discharging and carrier gas. And a custom-built AC high-voltage power supply with a total power consumption of 5 W, frequency of 2-4 kHz, and amplitude around 1-5 kV_p-p was used. This LTP source is a soft ionization source. The initial performance of the ionization source has been evaluated by ionizing samples including alcohols, ketones, aldehydes and aromatics. These compounds cover most of the common air pollutants concerning people's health. It is well known that those plasmas generated by dielectric barrier discharge (DBD) produce significant amount of metastable species and electrons with mean energies greater than several electronvolt, but minimal fragmentation was observed in our work. Protonated ions are the dominant product for the VOCs detected after the ionization process. Further work has been conducted to confirm the detection feature of this source. The results are promising enough to ensure the novel LTP ionization source as an effective tool for the online detection of indoor VOCs.     

Detection of volatile organic compounds using surface enhanced Raman spectroscopy substrates mounted on a thermoelectric cooler

Preliminary results for a volatile organic compound (VOC) sensor based on surface enhanced Raman spectroscopy (SERS) are described. The sensor is comprised of a SERS substrate mounted on a thermoelectric cooler (TEC). The SERS substrate is chemically modified with a thiol coating that prevents oxidation of the roughened silver surface and attracts the analyte of interest to the SERS surface. Using this sensor, detection of chlorinated solvents, aromatic compounds, and methyl t-butyl ether (MTBE) is demonstrated.