MnO2/Al2O3催化剂-微气泡臭氧体系催化降解喹啉及其机理

制备了纳米MnO₂,并以Al₂O₃为载体制备了掺杂型MnO₂/Al₂O₃颗粒催化剂.催化剂焙烧温度和时间分别为500℃和4 h、MnO₂质量分数为8%时,催化剂具有最高的臭氧催化氧化活性.SEM分析表明,纳米MnO₂均匀分布于Al₂O₃载体表面.MnO₂/Al₂O₃催化剂的比表面积（BET）为183.22 m²·g^-1,平均孔容为0.27 cm³·g^-1,平均孔径为4.87 nm.建立了MnO₂/Al₂O₃催化剂-微气泡臭氧催化反应体系,研究了该体系对喹啉的降解去除效果及其机理.臭氧微气泡的平均粒径为61.7 μm.微气泡臭氧投量为30 mg·L^-1时,反应60 min后喹啉去除率能达到95%以上;反应20 min后,MnO₂/Al₂O₃催化剂-微气泡臭氧体系对实际煤化工废水二级出水的TOC去除率可达到55%以上.以叔丁醇作为分子探针,证明了羟基自由基（·OH）氧化作用在臭氧微气泡催化氧化体系中对喹啉的降解起到主导作用.     

Al2O3催化臭氧化处理邻苯二甲酸二甲酯

'Al₂O₃催化剂对邻苯二甲酸二甲酯(DMP)溶液臭氧化过程的影响结果表明:Al₂O₃可以显著提高臭氧氧化的效果,反应120min后,TOC的去除率从单独臭氧氧化的23.9%提高到55.1%.实验中还考察了制备条件对Al₂O₃催化剂活性的影响并确定了反应的最佳工艺条件.在实验考察的范围内:焙烧温度600℃,Al₂O₃粒径为0.5～1.0mm时催化活性最高;最佳反应工艺条件为:催化剂投加量20g/L,混和气体流速200mL/min,反应温度15℃.通过单独臭氧氧化,单独臭氧氧化后再进行催化剂吸附,催化臭氧化的对比实验证明了Al₂O₃催化剂对体系TOC的去除主要是基于催化作用.     

掺杂La或Si对Ag/Al2O3催化剂热稳定性和脱NO活性的影响

利用 BET比表面测定和 X-射线衍射技术考察了掺杂 La或 Si的 Ag/Al₂O₃催化剂的热稳定性 ,并研究了富氧条件下 ,丙烯在这些催化剂上选择性还原 NO的活性 .结果表明 ,掺杂 La或 Si能抑制 Al₂O₃相变 ,使 γ-Al₂O₃完全转化为 α-Al₂O₃的温度升至 1100℃以上 .相应地 ,延缓催化剂比表面下降 ,从活性角度来看 ,当焙烧温度为 1100℃时 ,与掺杂 La或 Si相比 ,不掺杂 La或 Si的 Ag/Al₂O₃催化剂活性要低得多 ;当焙烧温度低于 1000℃时 ,掺杂少量 La(2 % La₂O₃)对 Ag/Al₂O₃催化剂活性影响不大 ,但是 ,掺杂 Si(2%或 8% SiO₂)或较高含量 La(8% La₂O₃)会导致催化剂活性降低 .综合考虑热稳定性和富氧条件下的 NO还原活性 ,认为掺杂较低含量 La(2% La₂O₃)的 Ag/Al₂O₃催化剂性能最佳 .     

Pt颗粒负载对CeO2臭氧催化氧化甲苯的增强作用

通过铂颗粒吸附法制备得到Pt/CeO₂催化剂应用于臭氧催化氧化甲苯反应,研究了Pt颗粒负载对CeO₂臭氧催化氧化甲苯的增强作用.采用氢气程序升温还原（H₂-TPR）、氧气程序升温脱附（O₂-TPD）、X射线光电子能谱（XPS）和拉曼光谱（Raman）等手段对催化剂进行表征,结果显示,CeO₂负载Pt颗粒后,Pt与CeO₂存在相互作用,提高了CeO₂上氧空位的含量.臭氧分解实验证实了Pt/CeO₂催化剂具有更好的臭氧分解性能.臭氧催化氧化甲苯评价结果表明,Pt/CeO₂具有比CeO₂更优异的催化性能,在80 ℃时甲苯降解率、CO₂产率和臭氧分解率分别达到92.3%、92.1%和99.9%.原位拉曼进一步研究了臭氧分解生成的氧物种种类及含量,以及甲苯存在时氧物种的变化,结果表明,臭氧在氧空位上分解产生的过氧物种较为稳定,是氧化甲苯的重要活性物质.因此,Pt颗粒负载在CeO₂上能增强臭氧在催化剂上分解,并形成更多过氧物种,最终提升臭氧催化氧化甲苯的性能.     

垃圾焚烧中吸附剂对Cd、Pb迁移分布的影响

利用管式炉和模拟垃圾,研究了焚烧过程中SiO₂、Al₂O₃、CaO等吸附剂对重金属Cd、Pb迁移分布的影响规律,考察了不同吸附剂添加量、管式炉反应温度和停留时间的影响.结果表明,在各反应温度下,SiO₂、Al₂O₃、CaO均有利于Cd停留在底渣中;对于Pb,SiO₂、Al₂O₃亦使其易于停留在底渣中,而CaO在高温时表现为使Pb更易于向飞灰迁移.上述影响的程度均随着吸附剂添加量的增加而增加.当反应炉温度为850℃时,各吸附剂对于Cd的吸附效果顺序为CaO>Al₂O₃>SiO₂,对Pb的顺序为Al₂O₃>SiO₂>CaO.反应炉温度和停留时间的增加,也都易于使Cd、Pb向飞灰迁移.     

碳包覆Pd/Al2O3催化剂催化4-溴苯酚加氢脱溴的活性和稳定性调控研究

在污染物液相催化加氢脱卤过程中，提高催化剂的稳定性至关重要.以水热合成法制备了不同碳包覆量的Pd/Al₂O₃@C催化剂，对催化剂进行了系列表征，并将催化剂应用于4-溴苯酚（4-BP）污染物的催化加氢脱溴反应.表征结果显示碳层提高了Pd/Al₂O₃的表面疏水性，有利于4-BP在催化剂上的吸附.并且在Pd/Al₂O₃@C催化剂的碳化过程中，碳还原部分Pd颗粒，并保留部分正价态Pd活性位，增强了4-BP中C-Br键的活化.与Pd/Al₂O₃相比，碳涂层提高了催化剂的催化活性.但当碳包覆量超过最佳包覆量后，暴露的Pd粒子随碳包覆量的增加而减少，导致活性下降.此外，碳层修饰后，催化剂的稳定性显著提高，从而大大抑制了Pd粒子的团聚和损耗.Pd/Al₂O₃@C表面的碳涂层对卤素具有较高的耐受性，从而减轻了液相催化加氢脱卤反应中活性中心的中毒.     

Al2O3为载体的催化剂净化贫燃汽车尾气研究

在富氧条件下,考察了C₃H₆和C₂H₅OH在Ag/Al₂O₃、In/Al₂O₃、Sn/Al₂O₃、Co/Al₂O₃、Pt/Al₂O₃和Ag/Al₂O₃+Pt/Al₂O₃组合催化剂上选择性还原NO的性能.结果表明,Ag/Al₂O₃具有最高的NO还原活性.在负载型过渡金属氧化物催化剂上,会生成显著量的CO,其HC和CO氧化转化温度也远远高于Pt/Al₂O₃催化剂.串联组合Ag/Al₂O₃+Pt/Al₂O₃催化剂可显著拓宽活性温度范围,促进HC和CO氧化,降低N₂O和CH₃CHO生成量.     

羧酸类有机物催化湿式氧化过程中ZnFe0.25Al1.75O4催化剂的稳定性研究

草酸、甲酸和乙酸是催化湿式氧化过程3种最主要的小分子羧酸类中间产物．比较了ZnFe_0.25Al_1.75O₄催化剂降解这3种物质时的催化活性和铁离子溶出量的大小．160℃下草酸是唯一可被完全降解的物质,降解过程中铁溶出量高达9.5 mg·L^-1;而甲酸和乙酸对铁离子稳定性影响很小．由于草酸具有很强的酸性和还原性,铁溶出量在氮气气氛中比在氧气气氛中大．ZnFe_0.25Al_1.75O₄催化剂对水杨酸也具有很高的降解活性和稳定性．     

高压放电等离子体协同锰锆镧铈催化剂降解乙酸乙酯的特性与机制

实验制备了新型Mn-Zr-La-Ce/Al₂O₃、Mn-Zr-Cu和Mn-Co-Ce 3种催化剂,利用SEM-EDS、XRD、BET、FT-IR、O₂-TPD进行表征分析,研究了高压放电协同催化剂对乙酸乙酯的降解因素影响规律（催化剂种类、初始浓度、含氧量和进气气量）,通过对出口气体GC-MS等分析,探讨了高压放电协同催化降解乙酸乙酯的机理.结果表明,高压放电低温等离子体协同Mn-Zr-La-Ce催化剂对于乙酸乙酯的降解效果最好,当电压为40 kV时,降解效率为94.6%,能量效率为1.52 g·kW^-1·h^-1,降解副产物O₃及NO_x浓度较低.降解效率随着初始浓度、气量的增加而较低,但随着含氧量的增加则是先升高后下降.GC-MS等分析结果表明,在降解乙酸乙酯过程中会产生丙酸乙酯和乙酸正已酯等中间产物,最终生成CO₂、H₂O.     

富氧条件下SnO2/Al2O3催化剂上丙烯选择性还原NOx的研究

考察了分别用浸渍法、共沉淀法和溶胶-凝胶法制备的SnO₂/Al₂O₃催化剂上丙烯选择性还原NO_x的催化活性,发现制备方法与Sn的负载量对其活性有重要影响.溶胶-凝胶法制备的SnO₂/Al₂O₃催化剂活性最高,Sn的最佳负载量为5%.与浸渍法和共沉淀法制备的5%SnO₂/Al₂O₃催化剂相比,溶胶-凝胶法制备的5%SnO₂/Al₂O₃催化剂受水蒸汽的抑制作用较弱,并且在水和SO₂共存的条件下活性最高.此外,反应气中丙烯及氧气浓度的增加有利于NO_x转化率的提高.     

两种放电模式降解甲苯的原位红外研究

采用原位红外对比研究连续放电法和吸附存储-放电法两种降解方式下,γ-Al2O3、Ag/γ-Al2O3、NiO/γ-Al2O3三种催化剂上甲苯的吸附和降解反应,对该过程中催化剂表面中间产物的变化以及催化剂对甲苯降解的作用进行考察.结果表明,吸附存储-放电法要优于连续放电法,其中间产物的种类相对减少,未检测到胺类物质;主要原因是吸附存储-放电模式下的催化剂可以有效利用等离子体产生的活性物种,使中间产物迅速脱附转化.对比γ-Al2O3、Ag/γ-Al2O3、NiO/γ-Al2O3三种催化剂对甲苯的降解作用,结果显示Ag、NiO的添加能有效减少中间产物的累积,其中NiO/γ-Al2O3表现出更良好的效果.     

Pt/CeO2催化氧化甲苯反应机制研究

采用浸渍法制备了Pt/CeO_2和Pt/Al2O_3催化剂,并通过XRD、BET、ICP-OES、H2-TPR、XPS等手段表征其物理化学性质.结果发现,Pt/CeO_2和Pt/Al2O_3催化剂上Pt负载量约为0.6%,Al2O_3载体上Pt颗粒尺寸更小,Pt/CeO_2的可还原性更强.甲苯催化氧化活性评价结果表明,Pt/CeO_2催化剂表现出更好的催化活性,T50=170℃,T90=190℃.通过UV-Raman、甲苯TPD、GC/MS、In-situ FTIR等手段进一步研究发现,Pt/CeO_2活化甲苯及反应供氧的机制与Pt/Al2O_3存在区别,其活性更好是因为:(1)负载在CeO_2表面存在高电子密度的Pt原子,具有更强的活化甲苯能力,可以直接使苯基和甲基间的C—C链发生断裂;(2)Pt的负载促进了CeO_2氧空位形成,进一步提高了CeO_2的储氧性能,加速氧循环.除了Pt解离气相氧之外,CeO_2还可以提供活性氧物种参与催化氧化甲苯的反应,进一步提高甲苯催化氧化效率.     

污泥掺烧过程中Cl/S/P/矿物质的热交互作用对Cd迁移转化行为的影响

采用化学热力学平衡分析方法,应用污泥实测数据模拟计算了污泥掺烧过程中Cl/S/P与矿物质的交互作用,重点模拟研究了Cl/S/P/矿物质交互体系对Cd迁移转化的影响.研究结果表明,污泥掺烧过程含Cl、S及P逸出气体以HCl(g)、SO_2(g)及(P_2O_5)_2(g)形式排放.污泥掺烧含有CaO-SiO_2-Al_2O_3体系中,CaO可以抑制S以SO_2(g)释放,而SiO_2及Al_2O_3对SO_2(g)逸出有促进作用,同时CaO及Al_2O_3可以抑制P的挥发.污泥掺烧过程中SiO_2及Al_2O_3对Cd挥发都有一定抑制作用,但CaO及Fe_2O_3对Cd基本无影响;当Cl存在时,Ti O2和SiO_2对Cd吸附作用减弱,并使Al_2O_3吸附剂失效;当S存在时,可导致吸附剂对Cd中毒,而P可导致Al_2O_3吸附剂失效;Cl-S-P耦合体系中,单一矿物质对Cd迁移转化影响主要受Cl和S控制.SiO_2+CaO+Al_2O_3共存体系中,Cl的存在可导致固体吸附剂SiO_2和Al_2O_3失效;S、S+Cl、S+P、S+Cl+P的存在受控元素为S,并且可以抑制Cd的挥发;P、Cl+P的存在对Cd影响受控元素为Cl,可促进Cd挥发.     

Catalytic activity of cerium-doped Ru/Al2O3 during ozonation of dimethyl phthalate

In this paper, factors influencing the mineralization of dimethyl phthalate (DMP) during catalytic ozonation with a cerium-doped Ru/Al₂O₃ catalyst were studied. The catalytic contribution was calculated through the results of a comparison experiment. It showed that doping cerium significantly enhanced catalytic activity. The total organic carbon (TOC) removal over the doped catalyst at 100 min reached 75.1%, 61.3% using Ru/Al₂O₃ catalyst and only 14.0% using ozone alone. Catalytic activity reached the maximum when 0.2% of ruthenium and 1.0% of cerium were simultaneously loaded onto Al₂O₃ support. Results of experiments on oxidation by ozone alone, adsorption of the catalyst, Ce ion’s and heterogeneous catalytic ozonation confirmed that the contribution of heterogeneous catalytic ozonation was about 50%, which showed the obvious effect of Ru-Ce/Al₂O₃ on catalytic activity. __________ Translated from China Environmental Science, 2006, 26(4): 445–448 [译自: 中国环境科学]     

Photocatalytic decomposition of acrylonitrile with N–F codoped TiO2/SiO2 under simulant solar light irradiation

The solid acid catalyst, N–F codoped TiO₂/SiO₂ composite oxide was prepared by a sol–gel method using NH₄F as nitrogen and fluorine source. The prepared materials were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS), UV–Visible diffuse reflectance spectroscopy (UV–Vis), ammonia adsorption and temperature-programmed desorption (NH₃-TPD), in situ Fourier transform infrared spectroscopy (FT-IR) and N₂ physical adsorption isotherm. The photocatalytic activity of the catalyst for acrylonitrile degradation was investigated under simulant solar irradiation. The results showed that strong Lewis and Brønsted acid sites appear on the surface of the sample after N–F doping. Systematic investigation showed that the highest photocatalytic activity for acrylonitrile degradation was obtained for samples calcined at 450°C with molar ratio (NH₄F to Ti) of 0.8. The degradation ratio of 71.5% was achieved with the prepared catalyst after 6-min irradiation, demonstrating the effectiveness of photocatalytic degradation of acrylonitrile with N–F codoped TiO₂/SiO₂ composite oxide. The photocatalyst is promising for application under solar light irradiation. Moreover, the intermediates generated after irradiation were verified by gas chromatography–mass spectrometry (GC–MS) analysis and UV–Vis spectroscopy to be simple organic acids with lower toxicity, and the degradation pathway was also proposed for acrylonitrile degradation with the prepared catalyst.     

硅铝比和NiO对ZSM-5协同低温等离子体降解甲苯的影响

研究了不同硅铝比的ZSM-5与Ni/ZSM-5分子筛协同低温等离子体技术对甲苯降解性能的影响.以Ni O(Nickel Oxide)为活性组分,采用浸渍法对ZSM-5分子筛进行改性,利用氮气吸附脱附(BET)、X射线衍射仪(XRD)、X射线光电子能谱分析(XPS)、H_2程序升温还原(H_2-TPR)、NH_3程序升温脱附(NH_3-TPD)、Toluene程序升温脱附(Toluene-TPD)等技术表征样品的物理化学性质.考察了硅铝比对ZSM-5与Ni/ZSM-5分子筛体系中甲苯的吸附性能,研究了不同放电电压下硅铝比对甲苯降解率、碳平衡及二氧化碳选择性的影响,并采用气相色谱-质谱联用仪(GC-MS)分析了催化剂表面的有机产物.结果表明:硅铝比不但影响分子筛本身的物理化学特性(比表面积、氧化还原性能、表面酸性、疏水性等),还会影响Ni的负载形态和方式,更高的硅铝比与Ni O的负载能促进甲苯深度氧化,减少副产物,提高碳平衡和二氧化碳选择性.     

Mo-modified Pd/Al2O3 catalysts for benzene catalytic combustion

Mo-modified Pd/Al2O3catalysts were prepared by an impregnation method and tested for the catalytic combustion of benzene. The catalysts were characterized by N2 isothermal adsorption, X-ray diffraction（XRD）, X-ray photoelectron spectroscopy（XPS）, temperatureprogrammed desorption of NH3（NH3-TPD）, H2temperature-programmed reduction（H2-TPR）, and high-angle annular dark-field scanning transmission electron microscopy（HAADF-STEM）. The results showed that the addition of Mo effectively improved the activity and stability of the Pd/Al2O3catalyst by increasing the dispersion of Pd active components, changing the partial oxidation state of palladium and increasing the oxygen species concentration on the surface of catalyst. In the case of the Pd-Mo/Al2O3catalyst,benzene conversion of 90% was obtained at temperatures as low as 190°C, which was 45°C lower than that for similar performance with the Pd/Al2O3catalyst. Moreover, the 1.0% Pd-5% Mo/Al2O3catalyst was more active than the 2.0% Pd/Al2O3catalyst. It was concluded that Pd and Mo have a synergistic effect in benzene catalytic combustion.     

Toluene decomposition performance and NOx by-product formation during a DBD-catalyst process

Characteristics of toluene decomposition and formation of nitrogen oxide (NO_x) by-products were investigated in a dielectric barrier discharge (DBD) reactor with/without catalyst at room temperature and atmospheric pressure. Four kinds of metal oxides, i.e., manganese oxide (MnOx), iron oxide (FeOx), cobalt oxide (CoOx) and copper oxide (CuO), supported on Al₂O₃/nickel foam, were used as catalysts. It was found that introducing catalysts could improve toluene removal efficiency, promote decomposition of by-product ozone and enhance CO₂ selectivity. In addition,NO_xwas suppressedwith the decrease of specific energy density (SED) and the increase of humidity, gas flow rate and toluene concentration, or catalyst introduction. Among the four kinds of catalysts, the CuO catalyst showed the best performance in NO_x suppression. The MnOx catalyst exhibited the lowest concentration of O₃ and highest CO₂ selectivity but the highest concentration of NOx. A possible pathway for NOx production in DBD was discussed. The contributions of oxygen active species and hydroxyl radicals are dominant in NOx suppression.     

不同孔径HZSM-5协同低温等离子体催化降解甲苯性能研究

研究了HZSM-5分子筛孔径对其在等离子体场内催化降解甲苯的影响.采用化学液相沉积法对HZSM-5分子筛进行改性,利用XRD、氮气吸附脱附等方法表征样品的骨架结构和表面性质,并用择形吸附实验对样品孔径进行表征.同时,评价了HZSM-5分子筛体系中降解甲苯的性能,研究了分子筛吸附甲苯性能及臭氧的产量,并采用飞行时间质谱(TOF-MS)和气相色谱-质谱联用仪(GC-MS)分析了反应产生的有机副产物.结果表明:液相沉积法成功调控了HZSM-5孔径,样品孔径随沉积剂用量增加而减小;同时,样品均具有相同的MFI骨架结构,比表面积和孔容相差不大.HZSM-5的孔径尺寸对甲苯去除率影响不大,但对碳平衡有影响,孔径越大,碳平衡越好.孔径较大的HZSM-5分子筛对甲苯具有更大的吸附速率和吸附容量,同时更多臭氧参与反应,生成·OH和O·,促进甲苯深度氧化,减少副产物,提高碳平衡.     

Toluene decomposition performance and NOx by-product formation during a DBD-catalyst process

Characteristics of toluene decomposition and formation of nitrogen oxide (NOx) by-products were investigated in a dielectric barrier discharge (DBD) reactor with/without catalyst at room temperature and atmospheric pressure. Four kinds of metal oxides, i.e., manganese oxide (MnOx), iron oxide (FeOx), cobalt oxide (CoOx) and copper oxide (CuO), supported on Al₂O₃/nickel foam, were used as catalysts. It was found that introducing catalysts could improve toluene removal efficiency, promote decomposition of by-product ozone and enhance CO₂ selectivity. In addition, NOx was suppressed with the decrease of specific energy density (SED) and the increase of humidity, gas flow rate and toluene concentration, or catalyst introduction. Among the four kinds of catalysts, the CuO catalyst showed the best performance in NOx suppression. The MnOx catalyst exhibited the lowest concentration of O₃ and highest CO₂ selectivity but the highest concentration of NOx. A possible pathway for NOx production in DBD was discussed. The contributions of oxygen active species and hydroxyl radicals are dominant in NOx suppression.