生物流化床反应器在处理含氯代芳香化合物废水中的应用

氯代芳香化合物是工业废水中重要污染物之一。本文介绍了氯代芳香化合物的降解机理、生物流化床的特点及其处理氯代芳香化合物的应用，为含氯代芳香化合物的废水处理提供参考。     

有机化合物动态定量结构——生物降解关系(QSBR)模型研究

本文通过分析一般ＱＳＢＲ模型应用的特点、不足和影响有机物生物降解的基本因素，指出ＱＳＢＲ模型应综合反映影响有机物生物降解的四个方面（以氯代芳香化合物为例）：氯代苯系物的摄入、氯代苯系物的诱导作用、毒性物质的形成和基础酶的缺乏。在此基础之上给出了动态ＱＳＢＲ的概念模式及方法学基础。     

氯代芳香化合物的微生物降解研究

生物技术对消除有毒化学品已显示出广阔的应用前景，深入研究有毒化学品微生物降解的生物化学和遗传学，可按照预期目的构建具有更大降解能力的遗传工程菌株，以促使污染物的无害化资源化。本文对纯菌株降解氯代芳香化合物的降解途径、降解性质粒和遗传工程菌株的构建等诸方面进行了综述。     

芳香类污染物的厌氧生物降解研究

综述了国内外芳香类污染物厌氧降解的研究进展,详细阐述了含氮芳香类、氯代芳香类和酚类污染物厌氧降解的微生物类群与机理.提出了芳香类污染物生物降解今后发展方向的重点是共基质条件下生物降解性研究、厌氧-好氧条件下的生物降解性研究、高效工程菌和固定化细胞技术应用研究、构建基因工程菌和遗传学研究等技术领域.     

含氮芳香化合物的厌氧生物降解研究回顾

回顾了硝基芳香化合物和偶氮化合物在厌氧条件下的生物脱毒、转化和矿化作用的研究成果。这些研究表明 ,由于硝基和偶氮基具有强烈的吸电子性 ,好氧条件下很难降解。但是 ,硝基和偶氮基芳香化合物在产甲烷菌群作用下较易还原脱毒 ,转化为相应的芳香胺类 ,其毒性要小几个数量级 ,因而有些毒性很高的芳香化合物废水可利用厌氧反应器处理 ,而且反应过程中发现一些芳香胺类化合物可被完全矿化 ,表明一些含氮芳香化合物可作为厌氧菌的碳源和能源 ,在厌氧条件下被完全生物降解。     

溶剂萃取法分析水中卤代烃

和有机氯农药、多氯联苯等含氯化合物一样,氯代脂肪烃对环境的污染问题,也引起了人们的广泛的注意。这类化合物除了做为化工生产的中间品之外,另一主要用途就是做为溶剂,最终都会进入大气和水中,从而污染环境,对人体健康造成了潜在危协,目前已有关于氯仿致癌的报导。     

氯代芳香族化合物的生物降解性能

随着工农业生产的发展，进入环境的人工化合物越来越多，其中氯代芳香族化合物所占的比例也日趋增大。美国环保局（EPA）公布的129种优先控制污染物名单中，含卤有机化合物占一半以上（其中以含氯芳香族有机化合物为主）。我国公布的68种水环境优先控制污染物“黑名单”中，含氯芳香族有机化合物也占了很大的比重。由于它们广泛存在于制药、焦化、石油化工、农药等多种生产废水中，不仅毒性大，污染面也很广。研究氯代芳香族化合物的生物降解性能对其污染的控制具有十分重要的意义。本文拟就此方面的研究进展作一综述。1氯代芳香族化合物…     

环境中芳香胺类化合物的色谱检测方法研究进展

芳香胺类化合物具有致癌和致突变的作用,是环境优先控制污染物之一。芳香胺类化合物的检测方法很多,其中,色谱法具有分析速度快、线性范围宽、响应灵敏和检出限低的特点,是目前检测环境中芳香胺类化合物的常用方法。对水、土壤和大气三类不同环境样品中芳香胺类化合物的色谱检测方法进行了现状分析,论述了色谱检测方法的研究进展,并对今后的研究趋势进行了展望。     

1，4-二氯苯降解菌的分离及其降解特性研究

从某污水处理曝气池的活性污泥中分离出一株能够以1,4-二氯苯为唯一碳源和能源生长的菌株DEB-1,通过形态特征和生理生化试验初步鉴定为黄杆菌属（Flavobacterium sp.）。实验结果表明,该菌株最适降解温度为32℃、最适降解pH为7.8,24 h对100 mg/L的1,4-二氯苯的降解率达94.5%。菌株DEB-1的降解谱较广,对5种氯苯类物质具有较高的降解率。并进一步研究了DEB-1的1,4-二氯苯降解酶粗酶液的性质,其最适反应温度和pH分别为30℃和8.5。对处理含氯代芳香化合物的有机废水具有一定的意义。     

松花江中游(哨口-松花江村段)水中有毒有机物污染研究

1983—1990年,在松花江中游(哨口—松花江村)138公里江段中,进行七次五断面追踪水团采样,采用高分子微球GDX—502吸附富集,GC定性定量,GC/MS定性验证。依据有机物检出率、毒性持久性、有点源排放、分析方法适用等因素,筛选出65种主要有毒有机物。化合物总浓度逐年降低,石油烷烃、芳烃浓度增加;属致癌致变性化合物21种,EPA优测物21种,建议的优先控制黑名单20种;有点源排入的占90％以上,污染源来自吉化主要入江污水口;封冰期比其它水文期污染增强;该江段污染特征为氯代链烃、氯代苯类、硝基芳烃种类多、浓度高,应为重点控制对象。     

Chlorophenols and other related derivatives of environmental concern: properties, distribution and microbial degradation processes

Chlorophenols are chlorinated aromatic compound structures and are commonly found in pesticide preparations as well as industrial wastes. They are recalcitrant to biodegradation and consequently persistent in the environment. A variety of chlorophenols derivatives compounds are highly toxic, mutagenic and carcinogenic for living organisms. Biological transformation by microorganisms is one of the key remediation options that can be exploited to solve environmental pollution problems caused by these notorious compounds. The key enzymes in the microbial degradation of chlorophenols are the oxygenases and dioxygenases. These enzymes can be engineered for enhanced degradation of highly chlorinated aromatic compounds through directed evolution methods. This review underscores the mechanisms of chlorophenols biodegradation with the view to understanding how bioremediation processes can be optimized for cleaning up chloroaromatic contaminated environments.     

Formation and decomposition of chloroaromatic compounds in chlorine-containing benzene/oxygen flames

Premixed chlorine-containing, fuel-rich, low-pressure benzene/oxygen flames were analysed for the formation of (oxygenated) chloroaromatic compounds and their radicals by means of the condensation/radical-scavenging method (Hausmann, M., Homann, K.-H., 1995. Ber. Busenges. Phys. Chem. 99, 853-862). Several chlorinated organic compounds (methyl chloride, t-butyl chloride, chlorobenzene, chloroform) were used as additives within a maximum concentration of 10% of total fuel. Product identification and quantification were performed by GC/MS. The extent of formation of chloroaromatic compounds in these flames was largest in the cases of chlorobenzene and chloroform as additives. For chlorobenzene, 12 different chloroaromatics could be analysed in between C7H7Cl and C12H9Cl. Their formation is mainly due to conversion of initial chlorobenzene into substituted or oxidised derivatives, or growth products. Additional chlorination of aromatics is shown to be of minor importance in chlorobenzene-containing flames. Three isomeric (o/m/p) scavenging products could be identified for the chlorophenyl radical. In the chloroform case, 15 chloroaromatics could be analysed in between C6H5Cl and C14H9Cl. The weak C-Cl bond in chloroform is responsible for the high extent of chloroaromatics formation, either by Cl abstraction from the additive or by chlorination reactions via Cl radicals. Additionally, specific pathways to (di)chloroaromatics and chlorinated fulvene-type structures are outlined via CHCl2 and CCl2 radicals.     

Biodegradation capability of Absidia fusca Linnemann towards environmental pollutants

The purpose of this work was to study the bioremediation capability of Absidia fusca Linnemann (Zygomycete) towards different classes of xenobiotics (lignin-derived compounds, chloroaromatic compounds, polycyclic aromatic hydrocarbons) the presence of which in contaminated soils, water and sediments poses a significant risk to the environment and human health. Two strains from different origins were compared. One was from an official collection and grown in non-inducing conditions, while the other was isolated during the course of the survey of fungal flora in a polluted soil from Annaba (Algeria). All data were analyzed and results validated via a statistical treatment. We showed the effect of the factors studied (origin of the strain, xenobiotic) but also the interactions between these factors. The strain of A. fusca isolated from a polluted soil was able to efficiently degrade most of the xenobiotics tested, particularly: pentachlorophenol, phenol, catechol, guaiacol and ferulic acid. This property also existed in the other strain but at a very low level.     

Degradation of phenolic and chloroaromatic compounds by Coprinus spp

Three species of Coprinus: C. sp, C. cinereus and C. micaceus were compared on solid media for some aspects of their physiological behaviour and cultural requirements (temperature, pH, substrate). Constitutive extracellular enzymatic activities were also determined. The Coprinus spp. exhibited different physiological and cultural features. Cultures of the 3 Coprinus species in synthetic liquid medium showed an efficient degradation of phenolic lignin model compounds (catechol, ferulic acid, guaiacol, phenol, protocatechuic acid syringic acid and vanillic acid) and pentachloronitrobenzene, while pentachlorophenol was not metabolized after 5 days perhaps because of a strong adsorption on mycelial biomass. It was suggested that phenoloxidases were not necessarily required for the metabolization of these compounds. Coprinus species may share a common degrading system for monomeric phenolic and chloroaromatic compounds.     

高级氧化技术在含酚废水处理中的应用

合理高效地处理含酚废水是工业废水处理的主要任务之一。重点介绍了高级氧化技术 ,如超声波氧化、超临界水氧化、湿式氧化和光催化氧化等在含酚废水处理中的研究近况和应用前景 ,探讨了各种技术的应用和发展趋势     

Evaluation of the persistence of micropollutants through pure-oxygen activated sludge nitrification and denitrification.

The persistence of pharmaceuticals, hormones, and household and industrial chemicals through a pure-oxygen activated sludge, nitrification, denitrification wastewater treatment facility was evaluated. Of the 125 micropollutants that were tested in this study, 55 compounds were detected in the untreated wastewater, and 27 compounds were detected in the disinfected effluent. The persistent compounds included surfactants, fire-retardant chemicals, pesticides, fragrance compounds, hormones, and one pharmaceutical. Physical-chemical properties of micropollutants that affected partitioning onto wastewater solids included vapor pressure and octanol-water partition coefficients.     

Fenton氧化法预处理难降解高浓度化工废水

难降解高浓度化工废水直接采用生化法处理较为困难,为了减少后续水处理系统处理难降解物质的量,采用Fenton氧化法对难降解高浓度化工废水进行预处理且非常有效.重点考察了pH、投药比例、投药量以及反应时间对Fenton氧化法预处理高浓度化工废水的影响.经过实验得出最佳条件:pH为3.5,投药比例为1.0 mL 50％(质量...     

Hydrogenolysis of chlorobenzene,dichlorobenzenes and chlorotoluenes by in situ generated and gaseous hydrogen in alkaline media and the presence of Pd/C catalyst

A method for dechlorination of chloroaromatic compounds at room temperature and atmospheric pressure by an in situ generated––in reaction of Al particles with water––or gaseous hydrogen in alkaline media and the presence of Pd/C catalyst was thoroughly investigated, having in mind its possible application in utilization of organochlorine waste. Conversion degree to dechlorinated compounds depended on the constitution of substrates and ranged between 88% and 96% when in situ hydrogen was used (at substrate (chlorine) to catalyst molar ratio 550:1 and over twofold stoichiometric excess of Al relative to substrate (chlorine); the process lasted ca. 26 h until all Al was consumed), or 90–97% if gaseous hydrogen was purged. Effectiveness of dechlorination was markedly affected by stirring, i.e. size of the stirrer and speed of revolution. Prospects for application of the method described were briefly outlined.     

Reduction of pharmaceutically active compounds by a lagoon wetland wastewater treatment system in Southeast Louisiana

A number of pharmaceutically active compounds (PhACs) have been detected in the aquatic environment as a result of discharges of municipal wastewater. In the state of Louisiana, USA, many municipalities treat wastewater using natural systems, such as lagoons and wetlands, rather than conventional wastewater treatment technologies. Nearly all research to date has focused on the fate of PhACs in conventional treatment plants, not constructed and natural wetlands. In the wastewater treatment plant (WWTP) for Mandeville, Louisiana, USA, wastewater flows of 7600 m³ d⁻¹ are treated in a series of aeration lagoons (basins), followed by a constructed wetland and UV disinfection, before being discharged into a natural forested wetland (i.e. Bayou Chinchuba) and eventually, Lake Pontchartrain. Thirteen out of the 15 PhACs investigated were detected in the wastewater inflow to the treatment plant. Only 9 of the 13 compounds were above the detection limits at the treatment plant effluent. The concentrations of most compounds were reduced by greater than 90% within the plant, while carbamazepine and sotalol were only reduced by 51% and 82%, respectively. The percent reductions observed in the Mandeville system were greater than reduction rates reported for conventional WWTPs; perhaps due to the longer treatment time (∼30 days). Most target PhACs were not completely removed before discharge into Lake Pontchartrain, although their collective annual loading was reduced to less than 1 kg and down to ppb with significant potential for dilution in the large lake.