锐钛型TiO2对尿素热解过程的影响

通过实验的方法收集了不同温度下纯尿素和尿素/TiO₂混合物热解后的固体残留物，使用红外光谱（IR）及气相色谱质谱联机（GC-MS）方法对这些热解残留物进行成分分析；使用热重-红外联机（TG-FTIR）技术研究尿素及三聚氰酸在有无催化剂TiO₂的情况下的热解特性及气体产物的生成规律；根据Coats-Renfern方法对尿素热解第一阶段的非等温热失重率曲线的数据进行动力学研究，建立动力学方程。结果表明，100~250℃的尿素热解残留物中主要为尿素和缩二脲，300~400℃的尿素热解残留物中主要为三聚氰酸等含氮杂环有机化合物；锐钛型TiO₂能促进尿素和三聚氰酸的热解反应，缩短其反应进程，HNCO与水蒸气在TiO₂表面易发生反应；尿素第一阶段热解的反应级数为2，单独热解时活化能为113.25kJ/mol，指前因子A为2.01×10¹¹min^-1，在催化剂TiO₂的作用下，活化能E为77.42kJ/mol，指前因子A为4.82×10⁷min^-1。     

LaMnO3/生物炭催化剂低温NH3-SCR催化脱硝性能研究

以La-Mn钙钛矿氧化物为活性组分,生物炭为载体,利用浸渍法制备负载型脱硝催化剂LMO/BCNA。利用固定床反应装置考察了催化剂的催化活性以及耐硫耐水性能,100～250℃范围内,NO转化率>80%,N₂选择性>90%,225℃时NO转化率最高,为95.8%,对应的N₂选择性为95.4%。与氧化物相比,负载型催化剂的催化活性大幅提升,同时也扩宽了工作温度区间;生物炭载体的引入,减弱了催化剂对H₂O、SO₂的吸附,增强了耐硫耐水性能。应用稳态动力学方法构建催化反应动力学模型,在实验条件范围且O₂含量为5%时,催化NH₃-SCR反应过程中NO、O₂、NH₃的反应级数分别为0.66、0、0,并得到LMO/BCNA催化的反应活化能为25.52 k J/mol,低于商用钒钨钛催化剂的化学反应活化能(40～94 k J/mol)。     

低温等离子体用于柴油机尾气脱硝的实验

柴油机作为卡车、重型机械以及船舶的主动力装置仍被广泛采用,其尾气中氮氧化物的脱除技术也是目前的研究热点。本文搭建了模拟柴油机尾气的配气系统,采用介质阻挡放电产生低温等离子体（non-thermal plasma,NTP）的方法对模拟柴油机尾气进行了脱硝的实验研究。实验结果表明：针对本系统,电源效率和能量密度随着输入电压的增大而升高,当输入电压高于60V时,电源效率在90%以上;在O₂/N₂条件下,随着O₂浓度以及能量密度的增加,NO生成量逐渐增加,NO₂生成量先增加后降低最终趋于稳定;在NO/N₂条件下,低温等离子体对NO的脱除率接近100%;在NO/O₂/N₂条件下,随着NO浓度的增加,临界O₂浓度升高,O₂体积分数为1%时脱硝效率在90%以上,O₂体积分数高于14%时低温等离子体的脱硝率为负值,且随着能量密度的增加,生成的NO _x 浓度也更高,O₂浓度对低温等离子体的脱硝性能起决定性作用;在低能量密度时,加入NH₃会提高脱硝性能,高能量密度时NH₃会略微降低NTP的脱硝性能,当加入H₂O模拟真实柴油机尾气成分且喷氨时,获得的脱硝率最高为40.6%。     

汽车尾气净化三效催化剂中N2O和NH3的生成及控制研究进展

N₂O和NH₃的排放主要来自于机动车尾气排放。本文总结了近十几年来轻型汽油车N₂O和NH₃排放的研究进展,阐述了两种气态污染副产物在三效催化剂中的形成机理,通过对影响N₂O和NH₃生成的贵金属种类和含量、载体材料、不同气体组成和浓度、老化条件、不同车辆及测试工况、反应温度等主要影响因素的综述,总结了各要素对N₂O和NH₃形成的影响,得出N₂O和NH₃主要在富燃条件下冷启动阶段生成,NO的解离在N₂O和NH₃的生成中起关键作用;影响N₂O和NH₃生成的各因素之间相互关联,相互影响;催化剂的老化增加N₂O和NH₃的排放;贵金属Rh比Pd和Pt更有利于N₂O和NH₃的分解等结论。发动机、后处理策略系统的升级、更合适测试循环的开发以及催化剂的优化可以进一步降低N₂O和NH₃的排放。     

单空缺石墨烯负载的Pd单原子催化剂上NO还原的密度泛函理论研究

采用密度泛函理论（DFT）方法对单空缺石墨烯负载的Pd单原子（Pd/SVG）催化剂上H₂还原NO的反应进行了研究,探究了Pd/SVG上NO还原生成N₂和NH₃的路径。在Pd/SVG上NO容易加氢形成HNO,需要的活化能为67.0 kJ·mol^-1,显示了极高的催化活性。N₂生成的有利路径为NO活化生成HNO后,HNO继续加氢生成中间体NH₂O和NH₂OH,然后NH₂OH解离生成NH₂和OH,生成的NH₂中间体结合NO形成NH₂NO,然后NH₂NO异构化形成的NHNOH再经解离生成N₂与H₂O,这个过程中的决速步骤为NH₂NO分子内氢转移生成NHNOH,能垒为144.3 kJ·mol^-1。对于NH₃的生成,从NO的活化到中间体NH₂的形成与N₂的形成过程相同,最后NH₂加氢即可形成NH₃,这个过程中的决速步骤为NH₂O加氢生成NH₂OH,能垒为86.4 kJ·mol^-1。比较生成N₂和NH₃的决速步能垒可见,Pd/SVG催化剂上NO经H₂还原更容易形成NH₃。本研究为石墨烯负载型Pd基催化剂上H₂还原NO的实验及工业应用提供理论参考。     

混合载体锰基宽温SCR脱硝催化剂的研究

为制备宽温脱硝催化剂，采用机械研磨方法获得了TiO₂和ZSM-5混合载体，并采用浸渍法制备了负载型MnO_x/TiO₂-ZSM-5脱硝催化剂。对制得的催化剂进行了X射线衍射(XRD)、N₂等温吸附-脱附、H₂程序升温还原(H₂-TPR)、NH₃程序升温脱附(NH₃-TPD)和NO程序升温脱附(NO-TPD)等表征，并考察了其催化脱硝活性。结果表明：MnO_x/TiO₂-ZSM-5催化剂具有较大的比表面积、更多的表面活泼锰物种、较多的酸位点，其对低温NH₃和NO吸附量及高温NH₃吸附量均有所增加，从而表现出更好的脱硝催化活性，在200～350℃时NO转化率达99%以上。     

多针电晕放电协同Ag/TiO2纳米催化剂脱除空气中低浓度甲苯研究

采用多针电晕放电与Ag/TiO₂纳米催化剂的原位耦合构建等离子体催化系统，对系统的放电特性进行诊断，并对催化剂进行表征研究；研究等离子体催化系统对空气中低浓度甲苯的脱除性能，并监测系统脱除甲苯过程中产生的有害副产物臭氧；探讨等离子体催化系统脱除低浓度甲苯及控制副产物臭氧生成的内在机制。研究结果表明，当放电电压高于7.0 kV时，等离子体可弥散于整个放电间隙内，Ag/TiO₂纳米催化剂的涂覆未影响放电的正常进行，利于反应气体、等离子体及催化剂间的相互作用；Ag/TiO₂纳米催化剂的Ag粒子粒径约为6.5 nm，可以创造大量高活性Ag-TiO₂界面位点，并能吸收利用等离子体辐射的紫外-可见光；当放电电压为7.5 kV时，单纯多针电晕放电所得甲苯转化率与CO₂选择性分别为21%与7%，等离子体催化系统则使二者分别提升至83%与61%，并将过程中副产物臭氧的浓度由5.12 mg/m³降至0.02 mg/m³以下；多针电晕放电协同Ag/TiO<...     

水溶性聚磷酸铵-尿素硝酸铵-氯化钾体系在5℃下的固液相平衡研究

采用动态法测定了APP(水溶性聚磷酸铵,18-58-0)-[CO(NH₂)₂-NH₄NO₃]-KCl-H₂O体系及其子体系APP(18-58-0)-[CO(NH₂)₂-NH₄NO₃]-H₂O、KCl-[CO(NH₂)₂-NH₄NO₃]-H₂O、APP(18-58-0)-KCl-H₂O在5℃下的固液相平衡数据,利用XRD分析平衡固相物相组成。结果表明：APP(18-58-0)-[CO(NH₂)₂-NH₄NO₃]-H₂O、KCl-[CO(NH₂)₂-NH₄NO_3...     

乙醇胺对介质阻挡耦合电晕放电同时脱除NO、SO2的影响

采用自行设计的介质阻挡耦合电晕放电等离子体反应装置进行了模拟烟气同时脱硫脱硝的研究,分别考察乙醇胺（HOCH₂CH₂NH₂,MEA）在不同模拟烟气体系中对NO、SO₂脱除的影响,深入探讨了MEA在放电过程中与NO的作用机理。结果表明：在N₂/O₂/SO₂/NO体系中,0.56% MEA的加入可以显著消除O₂对NO脱除的抑制作用;在N₂/CO₂/SO₂/NO体系中,MEA会吸收进入体系中的部分CO₂,以减弱CO₂对NO脱除的抑制;在N₂/O₂/CO₂/H₂O/NO/SO₂体系中,0.56% MEA的加入既可以有效减弱H₂O的影响,也可以使NO的脱除率达到71.28%,继续将MEA的体积分数增大至1.20%时,可将该体系下NO脱除率提高到81.25%;同时,MEA可以在短时间内高效吸收体系内的SO₂,且几乎不受其他气体成分的影响,SO₂脱除率保持在95%左右。     

NTP转化C3H6/NO/N2气氛中NO及发射光谱分析

利用介质阻挡放电产生低温等离子体转化C₃H₆/NO/N₂气氛中NO,结合发射光谱诊断法研究了碳氢化合物C₃H₆对NO转化的影响。研究结果表明,随着放电功率的升高,NO转化率先升高后逐渐趋于平缓,NO₂浓度持续降低,N₂O浓度呈先升高后降低趋势,NO主要被还原为N₂;相同放电功率下,随着C₃H₆初始浓度升高,NO_x转化率和N₂O浓度升高、NO₂浓度降低;添加C₃H₆会降低N₂第二正带系和NO-γ带的发射光谱强度,产生CN自由基的激发跃迁谱线,影响NO的化学反应机制,同时生成了棕黄色的聚合物。     

Nitrous oxide reduction with ammonia over Co---MgO catalyst and the influence of excess oxygen

N₂O decomposition on Co---MgO was studied under high (6.67 kPa) and low (75 Pa) N₂O pressure and the effect of reductant (C₂H₆, NH₃) was studied. The activity decays because of the strong adsorption of oxygen produced, while the reductant removed the adsorbed oxygen giving a steady catalysis. The reaction between NH₃ and excess amount of O₂ produced N₂O as a main product. Although N₂O gives the same intermediate (O) as O₂ does, the former decomposition seems to proceed faster than the latter on Co---MgO. The reaction mechanism studied here was compared with the SCR (NO---NH₃ in O₂) reaction on V₂O₂-TiO₂. Since NH₃, N₂O and O₂ gives only N₂ and water, Co---MgO can be a possible catalyst used in the boiler exhaust to reduce N₂O concentration by adding ammonia.     

Development of a new Rh/TiO2–sepiolite monolithic catalyst for N2O decomposition

Monolithic catalysts based on Rh/TiO₂–sepiolite were developed and tested in the decomposition of N₂O traces. Several effects such as the presence of NO, O₂ and NO + O₂ in the gas mixture, the catalysts pre-treatment and the metal loading were evaluated. The system was extremely sensitive to the amount of rhodium, passing through a maximum in the catalytic activity at a Rh content of 0.2 wt.%. It has been demonstrated that both NO and O₂ compete for the same adsorption sites as N₂O; however, this effect was not as severe as for other previously reported Rh systems. For NO + O₂ gas mixtures the inhibition effect was stronger than when only NO or O₂ was present. Analysis of the pre-reduced sample by XPS showed Rh mainly in the metal state, even after treatment with N₂O + O₂ mixtures, suggesting that the oxygen consumption observed in the Temperature Programmed Reaction experiments was related to the oxygen uptake by vacancies in the support. The presence of sepiolite in the support preparation and its role as a matrix over which TiO₂ particles were distributed, seems to play an important effect in the migration process of oxygen species through the support vacancies. The Rh/TiO₂ monolithic system is an attractive alternative for the elimination of N₂O traces from stationary sources due to the combination of high catalytic activity with a low pressure drop and optimum textural/mechanical properties.     

溶胶-凝胶原位合成宽活性温度V2O5/TiO2脱硝催化剂

利用溶胶-凝胶技术原位合成一系列不同V₂O₅担载量的V₂O₅/TiO₂催化剂,通过BET、XRD、NH₃-TPD及紫外-可见光等手段对催化剂进行表征。结果表明：制备的催化剂均具有介孔结构,V₂O₅在TiO₂表面高度分散,且存在3种典型的酸性位。通过选择性催化还原反应对V₂O₅/TiO₂催化剂进行活性评价,结果显示随着V₂O₅含量的增加,NO转化率大于75%的温度窗口向低温方向偏移,含10% （质量分数）V₂O₅的催化剂的NO转化率为80%的温度窗口最宽为200～450℃,240℃时20 h连续实验表现出稳定的抗硫抗水性能。结合紫外-可见光谱分析,揭示了钒掺杂所形成的单聚和低聚钒酸盐为催化剂的活性组分。     

Alumina- and titania-based monolithic catalysts for low temperature selective catalytic reduction of nitrogen oxides

The selective catalytic reduction of NO+NO₂ (NO_x) at low temperature (180–230°C) with ammonia has been investigated with copper-nickel and vanadium oxides supported on titania and alumina monoliths. The influence of the operating temperature, as well as NH₃/NO_x and NO/NO₂ inlet ratios has been studied. High NO_x conversions were obtained at operating conditions similar to those used in industrial scale units with all the catalysts. Reaction temperature, ammonia and nitrogen dioxide inlet concentration increased the N₂O formation with the copper-nickel catalysts, while no increase was observed with the vanadium catalysts. The vanadium-titania catalyst exhibited the highest DeNO_x activity, with no detectable ammonia slip and a low N₂O formation when NH₃/NO_x inlet ratio was kept below 0.8. TPR results of this catalyst with NO/NH₃/O₂, NO₂/NH₃/O₂ and NO/NO₂/NH₃/O₂ feed mixtures indicated that the presence of NO₂ as the only nitrogen oxide increases the quantity of adsorbed species, which seem to be responsible for N₂O formation. When NO was also present, N₂O formation was not observed.     

Effect of different oxygen species originating from the dissociation of O2, N2O and NO on the selectivity of the Pt-catalysed NH3 oxidation

An effect of oxygen species formed from O₂, N₂O and NO on the selectivity of the catalytic oxidation of ammonia was studied over a polycrystalline Pt catalyst using the temporal analysis of products (TAP) reactor. The transient experiments were performed in the temperature range between 773 and 1073 K in a sequential pulse mode with a time interval of 0.2 s between the pulses of the oxidant (O₂, N₂O and NO) and NH₃. In contrast to adsorbed oxygen species formed from NO, those from O₂ and N₂O reacted with ammonia yielding NO. It is suggested that the difference between these oxidising agents may be related to the different active sites for dissociation of O₂, N₂O and NO, where oxygen species of various Pt-O strength are formed. Weaker bound oxygen species, which are active for NO formation, originate from O₂ and N₂O rather than from NO. These species may be of bi-atomic nature.     

低温燃烧下NH3的氧化特性

NH₃的气相氧化是低温燃烧过程中NO_x（NO和NO₂）与N₂O的重要来源,为了深入认识其反应规律,在管式流动反应器系统中进行了实验研究。重点考察了挥发分中的可燃气（CO、CH₄或H₂）和NO对NH₃氧化及氮氧化物排放的影响规律,并根据化学反应机理对实验结果进行了分析。研究结果表明,低温氧化性气氛下微量的可燃气就能够显著促进NH₃的氧化,并使NO_x和N₂O的生成量大幅度升高。当可燃气体浓度相同时,H₂对NH₃氧化的影响最大,CO的影响最小,CH₄对NH₃氧化的影响略大于CO。随着可燃气体浓度的升高,其对NH₃氧化与氮氧化物生成的影响先逐渐增加,然后趋于稳定。反应初始气体中存在NO时,也会加速NH₃的氧化。     

Partial oxidation of methane by O2 and N2O to syngas over yttrium-stabilized ZrO2

Catalytic partial oxidation of methane to synthesis gas over ZrO₂ and yttrium-stabilized zirconia (YSZ) is studied using O₂ and N₂O as oxidants. ZrO₂ is much more active than YSZ in oxidation of methane with N₂O. In contrast, YSZ is significantly more active than ZrO₂ when O₂ is used as an oxidant. The presence of O₂ does not influence the rate of N₂O decomposition over ZrO₂ and YSZ, while the presence of H₂O in the system decreases N₂O conversion significantly. O₂ and N₂O are activated at different active sites. Y-induced oxygen vacancies are active for O₂ activation, whereas oxygen co-ordinatively unsaturated Zr cations (Zr-CUS) located at corners, edges, steps and kinks are responsible for N₂O activation. These sites are also capable of dissociating H₂O, resulting in competition between H₂O and N₂O. As compared with N₂O, molecular O₂ is easier to be activated over YSZ and ZrO₂.     

NO reduction with NH3 over chromia–vanadia catalysts supported on TiO2: an in situ Raman spectroscopic study

In situ Raman spectroscopy was used for studying the ternary 2% CrO₃–6% V₂O₅/TiO₂ catalyst, for which a synergistic effect between vanadia and chromia leads to enhanced catalytic performance for the selective catalytic reduction (SCR) of NO with NH₃. The structural properties of this catalyst were studied under NH₃/NO/O₂/N₂/SO₂/H₂O atmospheres at temperatures up to 400 °C and major structural interactions between the surface chromia and vanadia species are observed. The effects of oxygen, ammonia, water vapor and sulfur dioxide presence on the in situ Raman spectra are presented and discussed.