非贵金属催化还原水中的硝酸盐氮

基于双金属催化还原NO3--N的机理分析和常见金属催化电解脱硝技术的初步研究成果,对非贵金属元素催化还原水中NO3--N进行了实验研究.实验数据表明,Fe、Cu、Co、Pb和Zn 5种元素在阴极电场作用下对NO3--N具有较高的催化还原活性;NO3--N催化还原主要产物为NO2--N和NH4＋-N,产物比例受催化元素选...     

以PHBV为固相碳源同时去除地下水中硝酸盐氮和对氯苯酚的试验研究

化肥和农药的施用导致中国的地下水中硝酸盐氮和农药污染同时存在,并成为威胁人体健康的重要因素之一。其中氯酚类物质是一类常见的农药,具有高毒性和难降解性。目前,关于固相反硝化用于硝酸盐氮和对氯苯酚同时去除的研究较少,并且对微生物群落结构演变情况的分析还鲜见报道。论文以聚羟基丁酸戊酸共聚酯(PHBV)为反硝化固体碳源,通过序批试验研究同步去除硝酸盐氮和对氯苯酚的效果,并探讨对氯苯酚的加入对反硝化速率的影响;利用末端限制性长度多态性分析(T-RFLP)技术,使用Alu I酶切总细菌16S r RNA,研究对氯苯酚的存在对微生物群落的影响。结果表明,(1)在50 mg·L-1的硝酸盐氮(NO3--N)的浓度水平下,对氯苯酚(4-CP)的加入前后,硝酸盐氮(NO3--N)的去除率为(97.5±1.2)%和(95.3±1.7)%,总体上使去除效果略有降低;在10 mg·L-1的质量浓度水平下,对氯苯酚24 h的平均去除率为45.4%,其去除85.5%是由于微生物的降解作用引起的。(2)从对氯苯酚的加入到第45天的时间内,反硝化速率表现为先下降后上升,说明对反硝化速率起到先抑制后促进的作用。(3)在对氯苯酚加入前后45 d内,系统微生物群落结构发生明显的变化,趋向于多样化和均匀化。     

紫外分光光度法同时测定生活饮用水中的硝酸盐氮和亚硝酸盐氮

提出了紫外分光光度法同时测定生活饮用水中的硝酸盐氮和亚硝酸盐氮的含量。方法操作简便快速,精密度和准确度都是令人满意,大大提高分析效率。     

Ni foam/Cu电极电催化还原硝酸盐氮

采用恒流电沉积法制备了泡沫镍/铜（Ni foam/Cu）电极.以Ni foam/Cu电极为阴极、Ti/RuO₂-Ir₂O₃电极为阳极构建电解体系,对水中硝酸盐氮进行电催化还原处理.并研究了电解质对总氮和氨氮去除率的影响和电极的稳定性.在一定范围内,增大电解质NaCl的浓度可以提高总氮和氨氮去除率.当NaCl浓度为0.5 g·L^-1时,在电解电流密度为8 mA·cm^-2的条件下对100 mg·L^-1 NO₃^--N溶液进行6次重复电解实验,2.5 h后硝酸盐氮去除率均可以达到94.5%以上.当NaCl浓度为1.25 g·L^-1时,在电解电流密度为8 mA·cm^-2的条件下对100 mg·L^-1 NO₃^--N溶液电解2.5 h,出水中氨氮浓度只有2.90 mg·L^-1,总氮去除率达到79....     

磁性壳聚糖凝胶微球固定反硝化菌去除地下水中硝酸盐氮

本研究从活性污泥中分离出氢自养反硝化细菌,在厌氧条件下利用氢气作为电子受体,将硝酸盐氮污染物彻底还原为氮气.通过原位共沉淀/柠檬酸钠交联法制备了一种磁性壳聚糖微球,将氢自养反硝化菌固定于磁性壳聚糖微球上组成固定化微生物反硝化体系.利用16SrDNA菌种鉴定、扫描电镜(SEM)、傅里叶红外光谱(FTIR)对固定化前后的材料进行了表征,并与游离的氢自养反硝化菌进行对比,同时进行静态批实验考察了在不同影响因素下硝酸盐去除效果.结果表明,分离出的氢自养反硝化菌属于陶厄氏菌属(MK928401),且被成功固定在磁性壳聚糖微球上;相同时间内,固定化氢自养反硝化菌对硝酸盐氮去除率高出游离细菌59%,说明固定化菌克服了由于游离菌易团聚而限制反硝化速率的缺点;磁性壳聚糖微球的加入,在一定程度上拓宽了氢自养反硝化菌对硝酸盐氮浓度的适应范围,同时拓宽了氢自养反硝化菌对pH的耐受范围;固定化氢自养反硝化菌经5次重复利用后,仍能高效还原硝酸盐氮,相比于游离细菌具有可回收和循环利用性.以上结果得出,以磁性壳聚糖微球固定氢自养反硝化菌,为高效去除地下水中的硝酸盐氮提供了一种更有效的途径.     

无机膜复合催化反应器脱除水中硝酸盐氮

利用Pd-Cu/Al2O3陶瓷膜对催化还原硝酸盐氮废水进行试验,通过在陶瓷膜中添加离子吸附树脂负载的催化剂Pd-Cu/H103,形成复合催化膜,并调整pH值与氢气流量,硝酸盐脱除转化率达到98%以上.     

多孔钛板负载Pd-Cu催化还原水中硝酸盐氮的研究

研究了多孔钛板负载Pd-Cu(1:1)催化剂作为阴极,利用电化学反应器脱除水中的硝酸盐氮,在pH值为6.4,电极板的电流密度为2.3mA·cm-2的条件下,以0.1g·1-1无水硫酸钠作为支持电解质,反应4h后,硝酸盐氮的去除率可以达到36%,出水浓度已接近饮用水标准,然而在此催化剂负载比例下对副产物氨氮的选择率非常高.反应在300mA,pH值为6.4时脱硝效果最高.在合适的浓度下,NO3-占优势地位,受竞争吸附影响小,同时电极板吸附位未达到饱和时,电催化反硝化反应符合表观一级反应动力学.另外,溶液的传质对反硝化没有显著影响;进水口的外露形成的水流跌落有利于NH3的逸出,反应溶液中的NH4 -N副产物减少,但是硝酸盐氮的去除效果受到影响.     

复合自养反硝化材料处理低碳氮比硝酸盐污水

作为一种典型的硝酸盐污水,低碳氮比硝酸盐污水的存在具有广泛性,且对生态环境和居民健康带来的危害日益突出.本研究构建了复合硫自养反硝化(CSAD)体系,基于硫-碳酸钙型复合材料与微生物,进行低碳氮比硝酸盐污水的深度处理,分析了材料投加量、粒径以及进水硝酸盐浓度对CSAD的影响,并探究了硝酸盐去除的动力学行为.结果 表明,...     

氮同位素控制下黄河及其主要支流硝酸盐来源分析

选取黄河小浪底水库及以下干流和支流河水为主要研究对象,利用氮同位素识别河水潜在硝酸盐来源,结果表明,研究区黄河干流及支流沁河和伊洛河河水硝酸盐含量均值分别为(4.77±0.95)、(3.45±1.71)和(4.50±0.91) mg·L-1.研究区黄河干流河水δ15N-NO3-均值为(+3.2±4.5)‰,上游河水硝酸盐来源主要为土壤有机氮矿化,下游平原区河水硝酸盐来源包括土壤有机氮矿化以及化学肥料.沁河河水δ15N-NO3-均值为(+8.3±4.6)‰,丰水期河水硝酸盐来源包括大气降水、土壤有机氮矿化以及化学肥料;平水期河水硝酸盐受到生活污水和土壤有机氮矿化共同影响;枯水期沁河河水由于断流形成封闭水体,浮游植物和藻类生长以及反硝化作用是控制河水硝酸盐的重要因素.枯水期洛河和伊河河水δ15N-NO3-值分别为+ 10.9‰和+3.4‰,其中生活污水是洛河河水硝酸盐的重要来源,合成化学肥料是伊河河水硝酸盐的重要来源.     

沉积贵金属Pt的Pt/TiO2膜利用可见光催化降解苯酚

采用溶胶-凝胶法制备锐钛矿纳米TiO2光催化材料,并用化学还原法还原氯铂酸溶液(H2PtCl6·4H2O)制备Pt胶体,然后滴涂在制备好的锐钛矿纳米TiO2基片上即对其进行贵金属修饰,从而得到纳米光催化材料Pt/TiO2膜.采用XRD、XPS、UV-Vis和SEM等手段对其表面理化特性进行了表征.以苯酚溶液为光催化降解...     

金属及其氧化物催化降解多氯联苯的研究进展

催化降解因其高的反应速率和降解彻底性,在氯代有机物的削减中得到广泛应用.目前研究较多的催化剂为零价态和氧化态的碱金属和碱土金属、过渡金属及贵金属,包括单金属和双金属两种.这类催化剂表面活性位点多样,在氯代有机物的降解中显示出优异的活性.多氯联苯(Polychlorinated Biphenyls,简称PCBs)是一类有毒难降解的持久性有机污染物.本文阐述了不同价态的单金属和双金属催化剂催化降解PCBs的反应机理,并介绍了影响反应速率和产物选择性的因素.并对金属及其氧化物催化降解PCBs的应用现状做了评述,对该技术的发展进行展望.     

催化臭氧化降解含微囊藻毒素污水

应用金属氧化物构建催化臭氧化工艺处理含微囊藻毒素污水,比较了不同催化剂的性能差异,分析了催化剂投加量、温度、pH、原水浓度对该工艺的影响.结果表明,选用CuO作催化剂能较好地处理含微囊藻毒素污水.温度与原水浓度对该工艺影响较小;催化剂投加量与pH是该工艺的主要影响因素.实验温度40℃、混合气体流量1.8 L.L-.1min-1、pH=9、催化剂投加量5 g.L-1、处理时间60 min,原水MC-LR去除率达到90%以上、COD去除率达到64%以上.处理20 min,该工艺催化作用去除MC-LR贡献率达到28%、去除COD贡献率达到52%.     

磁性海泡石吸附水中重金属离子的特性及机理

以化学共沉淀法制备磁性海泡石,通过设置一个外加磁场实现对其的分离回收.主要研究了磁性海泡石吸附水中重金属离子的特性,并结合XRD、FT-IR分析结果探讨了吸附机理,结果表明,磁性海泡石对重金属阳离子的吸附效果优于阴离子;初始pH对磁性海泡石吸附重金属离子的影响不仅取决于磁性海泡石表面的电荷性质,而且与重金属离子的水解能力有关;在吸附过程中,磁性海泡石的物相结构没有发生明显改变,吸附机理表现为离子交换和配合吸附作用.     

Forms of Nitrogen (NO 3 - -N; NO 2 - -N and NH 2 CONH 2 -N) and their relations to A.O.U. in the Indian coastal waters of Arabian Sea

The distribution of three important dissolved forms of nitrogen, viz. nitrate, nitrite and urea in the surface and bottom water samples collected from 27 selected hydrographic profiles, in the Arabian Sea, along the west coast of India is described. Of the three forms, nitrate concentrations were the highest and comparatively higher concentrations were observed in the bottom water. Decomposition of organic matter resulting in the release of the thermodynamically stable nitrogen species, i.e. nitrate, may be the major factor resulting in higher nitrate concentrations at these depths, where the water is also characterized by low values of dissolved oxygen and temperature. The significant positive correlation between A.O.U. and nitrate of the bottom water samples emphasizes the role of oxidative decomposition of organic matter which plays an active role in reducing the oxygen concentrations below the theoretical values since at this depth ( , 200 m) the net production is taken to be zero. This is also evidenced by the negative correlation of nitrate with dissolved oxygen and temperature, for the bottom samples.     

Degradation of Azo dye direct black BN based on adsorption and microwave-induced catalytic reaction

The novel microwave catalyst MgFe₂O₄-SiC was synthesized via sol-gel method, to remove azo dye Direct Black BN (DB BN) through adsorption and microwave-induced catalytic reaction. Microwave-induced catalytic degradation of DB BN, including adsorption behavior and its influencing factors of DB BN on MgFe₂O₄-SiC were investigated. According to the obtained results, it indicated that the pseudo-second-order kinetics model was suitable for the adsorption of DB BN onto MgFe₂O₄-SiC. Besides, the consequence of adsorption isotherm depicted that the adsorption of DB BN was in accordance with the Langmuir isotherm, which verified that the singer layer adsorption of MgFe₂O₄-SiC was dominant than the multi-layer one. The excellent adsorption capacities of MgFe₂O₄-SiC were kept in the range of initial pH from 3 to 7. In addition, it could be concluded that the degradation rate of DB BN decreased over ten percent after the adsorption equilibrium had been attained, and the results from the result of comparative experiments manifested that the adsorption process was not conducive to the process of microwave-induced catalytic degradation. The degradation intermediates and products of DB BN were identified and determined by GC-MS and LC-MS. Furthermore, combined with the catalytic mechanism of MgFe₂O₄-SiC, the proposed degradation pathways of DB BN were the involution of microwave-induced $OH and holes in this catalytic system the breakage of azo bond, hydroxyl substitution, hydroxyl addition, nitration reaction, deamination reaction, desorbate reaction, dehydroxy group and ring-opening reaction.

Open image in new window

     

Effects of support acidity on the reaction mechanisms of selective catalytic reduction of NO by CH4 in excess oxygen

The reaction mechanisms of selective catalytic reduction (SCR) of nitric oxide (NO) by methane (CH₄) over solid superacid-based catalysts were proposed and testified by DRIFTS studies on transient reaction as well as by kinetic models. Catalysts derived from different supports would lead to different reaction pathways, and the acidity of solid superacid played an important role in determining the reaction mechanisms and the catalytic activities. Higher ratios of Brønsted acid sites to Lewis acid sites would lead to stronger oxidation of methane and then could facilitate the step of methane activation. Strong Brønsted acid sites would not necessarily lead to better catalytic performance, however, since the active surface NO_y species and the corresponding reaction routes were determined by the overall acidity strength of the support. The reaction routes where NO₂ moiety was engaged as an important intermediate involved moderate oxidation of methane, the rate of which could determine the overall activity. The reaction involving NO moiety was likely to be determined by the step of reduction of NO. Therefore, to enhance the SCR activity of solid superacid catalysts, reactions between appropriate couples of active NO_y species and activated hydrocarbon intermediates should be realized by modification of the support acidity.     

不同加热方式下催化氧化甲苯的性能研究

研究考察了微波单模腔、多模腔与传统电炉三种不同加热方式下甲苯的催化氧化性能,分析不同加热方式下进出口气体温度和固定床反应温度的变化,并对实验前后的Cu-Mn-Ce/TiO2-分子筛催化剂进行了扫描电镜、X射线衍射和比表面积等表征测试.研究表明,相同工艺条件下电炉加热、微波多模腔与单模腔加热对甲苯的去除效率分别为77%、83%和94%,对应的床层反应温度为265℃、215℃和145℃,微波加热的选择性、"热点效应"和偶极极化作用提高了甲苯的降解效率并降低其氧化温度和工艺处理能耗,微波单模腔内高的能量密度显著提高了甲苯的氧化效率并降低反应温度.催化剂表征发现,微波加热对催化剂结构与活性组分的分布几乎没有影响,而电炉加热则导致催化剂表面烧结与活性组分团聚,微波加热下催化剂更大的比表面积有利于甲苯的吸附与氧化降解.     

高压脉冲放电等离子体活化NH3还原去除NO

NO如直接排放会引起酸雨、光化学烟雾等一系列大气环境问题,采用高压脉冲放电等离子体活化NH3还原去除NO,这种新方法结合了脉冲放电等离子体技术和催化还原技术的优点来提高NO的去除率。采用浸渍法制备催化剂V2O5/TiO2,用NH3作为还原气体,升温的同时利用针头作为阳极,大地作为阴极进行放电处理。结果表明,在有氧条件下(含氧量为10%),当V2O5含量为4.5%,温度为310℃,脉冲电源电压在14000～22000V变化时,NO的去除率可达95.3%。还探讨了放电等离子体活化NH3去除NO的机理。     

燃煤烟气脱硫副产物的重金属环境行为

通过理化分析、盆栽生物试验及土壤淋溶试验，探讨了脱硫副产物的重金属农业环境行为。结果表明：燃煤烟气脱硫副产物中的总Pb、Cd、Cr、As、Se、Ni、Cu等指标，基本上都低于国标最高容许量和土壤环境质量二级标准，符合国家控制标准，但普遍高于土壤自然背景值含量。8～10g／kg土的供试物量处理，花生、萝卜、甘蔗和水稻的可食部分重金属均无超常累积现象，未导致农产品重金属的富集残留污染，不影响农产品安全品质。在表土层供试物量达到40g／kg条件下，土壤淋溶试验结果表明，施脱硫副产物未导致土壤淋滤液重金属污染，不可能通过降雨淋溶过程，渗透过1m左右的土层而污染地下水源。