泉州市不同功能区土壤铅同位素组成及其来源分析

为查明泉州市土壤铅的污染来源,采集了泉州市不同功能区表层(O～20cm)土壤及城市环境污染端元(燃煤尘、汽车尾气尘、污泥)样品.采用ICP-MS测定土壤Pb含量,用热电质谱仪测定各样品的铅同位素组成.分析结果表明,泉州市不同功能区表层土壤已受到一定程度铅污染;泉州市土壤铅同位素208 Pb/(207+206)Pb和206Pb/207 Pb比值变化较大,分别为1.0769～ 1.1486和1.1150～1.2142;泉州市区各端元组分铅同位素组成差别比较大,可以有效示踪和鉴别泉州市区环境铅的污染来源.运用铅同位素示踪技术追踪土壤铅的污染来源结果表明,泉州市区土壤总铅同位素和可溶相铅同位素组成变化较大,土壤中铅来源较为复杂.交通繁忙区土壤铅污染主要来源于汽车尾气排放,农业区土壤铅主要来源于城市污泥与当地土壤背景,商业区土壤铅主要来源于城市污泥与燃煤尘及其煤渣的排放,居民区土壤铅污染主要受城市污泥与汽车尾气排放影响.     

温度对生物强化除磷工艺反硝化除磷效果的影响

以处理城市污水的中试规模生物强化除磷A2/O活性污泥工艺系统为研究对象,考察了温度对系统COD去除和脱氮除磷效果的影响,特别是温度对活性污泥反硝化除磷性能的影响.结果表明,当温度从(30.9±0.8)℃降低到(9.1±0.6)℃时,A2/O系统的脱氮除磷效果显著下降,系统对TN和TP的污泥去除负荷明显下降.通过污泥反硝化除磷活性实验发现,随着温度的降低,系统中活性污泥的最大厌氧释磷速率、最大好氧吸磷速率和最大缺氧吸磷速率都降低.活性污泥中反硝化除磷菌(DPB)占聚磷菌(PAOs)总量的比例随温度降低稍有下降,但平均值仍维持在47.5％左右.用阿伦尼乌斯公式对实验结果进行拟合,得到系统中活性污泥聚磷菌厌氧释磷反应活化能Ea1为148.0 kJ· mol-1,聚磷菌好氧吸磷反应活化能Ea2为228.8 kJ·mol-1,发生在缺氧条件下反硝化除磷菌的吸磷反应活化能Ea3为315.8 kJ·mol-1.对不同温度下污泥絮体粒径分析结果表明,随温度降低,粒径分布更加集中,系统中活性污泥絮体颗粒平均粒径减小,不利于污泥絮体内部反硝化除磷缺氧微环境的形成.     

二氧化钛复合型催化剂制备及其微波辅助催化氧化甲苯性能

实验采用溶胶凝胶法和传统浸渍法制备了TiO2-分子筛复合载体及复合载体负载过渡金属与稀土元素催化剂,通过微波辅助催化氧化甲苯的性能实验考察其催化活性.结果表明,复合TiO2明显提高了载体结构的稳定性与耐温性,并使过渡金属铜(Cu)、锰(Mn)和稀土元素铈(Ce)等活性组分在催化剂表面的分散更均匀;在复合载体吸附、吸波性能与多相活性组分催化的共同作用下,Cu-Mn-Ce/TiO2-分子筛催化剂微波辅助催化氧化甲苯的完全燃烧温度仅为175℃,此时甲苯去除率可达99％;15 h的连续性实验表明,TiO2复合型催化剂具有良好的催化活性与稳定性.由催化剂表征分析结果可知,活性组分颗粒的均匀分布与铜、锰氧化物及铜锰尖晶石固溶物等活性相的存在促进了甲苯的催化氧化,锐钛矿型TiO2较高的电子迁移速率与催化剂孔径的增大均有助于甲苯的氧化降解.     

呼和浩特市可镇污水处理厂工程设计

呼和浩特市可镇污水处理厂近期建设规模1.0×104m3/d,远期总规模2.5×104m3/d。污水处理主体工艺采用组合式A2/O生化池+砂滤,污泥处理采用污泥贮池+带式浓缩脱水一体机,尾水采用液氯消毒,设计出水水质执行GB 18918—2002《城镇污水处理厂污染物排放标准》一级A排放标准。介绍了该工程的工艺流程、设计参数,总结分析了工艺设计的技术特点。同时阐述了针对低温条件下的运行保障措施和要求,为寒冷地区同类污水处理厂的设计提供参考和借鉴。     

FY2 号气象卫星估算地面太阳辐射研究

综合考虑太阳因素、地形因素、地表积雪覆盖情况、云量以及非均质大气对太阳辐射的影响,基于FY2 号静止卫星构建晴空太阳总辐射计算模型,并利用山西省3 个辐射观测站2011 年逐时、逐日、逐月太阳总辐射观测资料对其估算结果进行检验。研究结果显示：逐时误差在±1 MJ·m^-2之间,逐日误差在±5 MJ·m^-2之间,表明模型计算的太阳辐射误差较小,稳定性较好;逐月误差结果显示,三个站模拟值都大于实测值,且误差趋势一致,均表现为冬季误差高于夏季;进一步对模拟值和实测值进行相关性分析,三站线性拟合度均在0.86～0.92 之间,且相关系数均达到显著相关水平,表明模型计算的太阳辐射准确性和精度较高,且在数值拟合上较好地反映了实际的太阳总辐射量,证实该模型应用于FY2 号气象卫星的可行性。     

基于废陶瓷的多孔陶瓷研制及其对Ni2+的吸附性能

通过SEM、XRD、FT-IR表征及多孔陶瓷对废水中镍的去除能力,确定多孔陶瓷的制备条件:原料中田菁粉掺杂质量分数为4%,焙烧温度为800℃.SEM和孔结构表征说明,焙烧使多孔陶瓷形貌、结构发生变化;随着焙烧温度的升高,多孔陶瓷的比表面积和孔容呈现降低的趋势,而孔径呈现增大的趋势;EDS分析能表明,原废瓷粉和多孔陶瓷的主要元素组成均为Si、Al、O.SEM、XRD和FT-IR分析表明,多孔陶瓷吸附前后结构稳定.吸附Ni2+的系列实验表明,多孔陶瓷用量为10 g·L-1,吸附时间为60 min,进水pH值为6.32,进水Ni2+浓度在100 mg.L-1以内.在此条件下废水的Ni2+去除率可达89.7%,多孔陶瓷对废水中镍有较好的去除效果.以制备的多孔陶瓷处理含镍废水,考察多孔陶瓷对废水中Ni2+的吸附动力学和吸附等温线,结果表明,多孔陶瓷对Ni2+的吸附过程符合准二阶动力学模型(R2=0.999 9),Qe为9.09 mg·g-1;吸附过程可用Freundlich方程和Langmuir方程来描述,温度由20℃升高至40℃,最大吸附量Qm由14.49 mg·g-1上升至15.38 mg·g-1.     

Biodegradation of 2-methylquinoline by Enterobacter aerogenes TJ-D isolated from activated sludge

Bacterial strain Enterobacter aerogenes TJ-D capable of utilizing 2-methylquinoline as the sole carbon and energy source was isolated from acclimated activated sludge under denitrifying conditions. The ability to degrade 2-methylquinoline by E. aerogenes TJ-D was investigated under denitrifying conditions. Under optimal conditions of temperature (35℃) and initial pH 7, 2-methylquinoline of 100 mg/L was degraded within 176 hr. The degradation of 2-methylquinoline by E. aerogenes TJ-D could be well described by the Haldane model (R² > 0.91). During the degradation period of 2-methylquinoline (initial concentration 100 mg/L), nitrate was almost completely consumed (the removal efficiency was 98.5%), while nitrite remained at low concentration (< 0.62 mg/L) during the whole denitrification period. 1,2,3,4-Tetrahydro-2-methylquinoline, 4-ethyl-benzenamine, N-butyl-benzenamine, N-ethyl-benzenamine and 2,6-diethyl-benzenamine were metabolites produced during the degradation. The degradation pathway of 2-methylquinoline by E. aerogenes TJ-D was proposed. 2-Methylquinoline is initially hydroxylated at C-4 to form 2-methyl-4-hydroxy-quinoline, and then forms 2-methyl-4-quinolinol as a result of tautomerism. Hydrogenation of the heterocyclic ring at positions 2 and 3 produces 2,3-dihydro-2-methyl-4-quinolinol. The carbon-carbon bond at position 2 and 3 in the heterocyclic ring may cleave and form 2-ethyl-N-ethyl-benzenamine. Tautomerism may result in the formation of 2,6-diethyl-benzenamine and N-butyl-benzenamine. 4-Ethyl-benzenamine and N-ethyl-benzenamine were produced as a result of losing one ethyl group from the above molecules.     

Effect of transition metal doping under reducing calcination atmosphere on photocatalytic property of TiO2 immobilized on SiO2 beads

TiO₂ immobilized on SiO₂ (TiO₂/SiO₂) have been prepared by sol-gel method and various ions of transition metals (Cr³⁺, Co²⁺, Ni²⁺, Cu²⁺, and Zn²⁺) were doped on the photocatalyst using wet impregnation method under reducing calcination atmosphere. The photocatalytic activity of metal doped TiO₂/SiO₂ towards phenol degradation under black light irradiation were investigated and compared with undoped TiO₂/SiO₂. The results showed that the photoresponse of Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂ were larger than undoped TiO₂/SiO₂, indicating that the photogenerated carriers were separated more efficiently in Cu²⁺ and Zn²⁺ doped TiO₂/SiO₂. The reactivity was in the order of Cu²⁺ > Zn²⁺ > Ni²⁺ > Cr³⁺ > Co²⁺. The different photoreactivity was ascribed to combine effect of the different ionic radii and photocorrison tendency of the dopants. The sample was also characterized by surface analytical methods such as X-ray diffraction, scanning electron micrograph/electron dispersive X-ray analyzer and UV-Vis absorption spectrum.     

Adsorption of 2-mercaptobenzothiazole from aqueous solution by organo-bentonite

The adsorption behavior of 2-mercaptobenzothiazole onto organo-bentonite was investigated.Natural bentonite from Gaozhou in Guangdong Province,China was collected.Organo-bentonite was prepared by intercalation of cetyltrimethyl ammonium bromide into the natural bentonite.The physicochemical properties of the prepared organo-bentonite were characterized by X-ray diffraction,N2 adsorption-desorption isotherm and Fourier transform infrared spectroscopy.The results showed that montmorillonite is the main component of the natural bentonite.The basal spacing of the natural bentonite is 1.47 nm,which increased to 1.98 nm on intercalation with cetyltrimethyl ammonium bromide.Moreover,both the surface area and pore volume increased with intercalation.Clear CH2 stretching(3000-2800 cm-1) and scissoring(1480-1450 cm-1) modes of the intercalated surfactants were observed for organobentonite.Compared with the pseudo first-order kinetic model,the pseudo second-order kinetic model is more suitable to describe the adsorption kinetics of 2-mercaptobenzothiazole onto organo-bentonite.The adsorption capacity of 2-mercaptobenzothiazole onto organo-bentonite increased with increasing initial concentration of 2-mercaptobenzothiazole,but decreased with increasing adsorbent dosage.The adsorption isotherm of 2-mercaptobenzothiazole onto organo-bentonite fits well with the Langmuir model.The maximum adsorption capacity of organo-bentonite for 2-mercaptobenzothiazole was 33.61 mg/g,indicating that organo-bentonite is a promising adsorbent for 2-mercaptobenzothiazole.     

Fe2O3 particles as superior catalysts for low temperature selective catalytic reduction of NO with NH3

Fe203 particle catalysts were experimentally studied in the low temperature selective catalytic reduction （SCR） of NO with NH3. The effects of reaction temperature, oxygen concentration, [NH3]/[NO] molar ratio and residence time on SCR activity were studied. It was found that Fe203 catalysts had high activity for the SCR of NO with NH3 in a broad temperature range of 150-270℃, and more than 95% NO conversion was obtained at 180℃ when the molar ratio [NH3]/[NO] = 1, the residence time was 0.48 seconds and 02 volume fraction was 3%. In addition, the effect of SO2 on SCR catalytic activity was also investigated at the temperature of 180℃. The results showed that deactivation of the Fe2O3 particles occurred due to the presence of SO2 and the NO conversion decreased from 99.2% to 58% in 240 min, since SO2 gradually decreased the catalytic activity of the catalysts. In addition, X-ray diffraction, Thermogravimetric analysis and Fourier transform infrared spectroscopy were used to characterize the fresh and deactivated Fe2O3 catalysts. The results showed that the deactivation caused by SO2 was due to the formation of metal sulfates and ammonium sulfates on the catalyst surface during the de-NO reaction, which could cause pore plugging and result in suppression of the catalytic activity.