环保型二次锌电极的研究

为了保护环境 ,减小污染 ,节约金属资源 ,十分有必要研究和开发环保型二次锌电极。本文提出了在表面覆盖稀土氢氧化物膜的二次锌电极的新思想 ,首先利用恒电位电解的方法在电极表面成功地覆盖一层均匀致密的稀土氢氧化物膜 ,再用恒电位电解、循环伏安、模拟充放电等实验方法 ,全面考察了稀土氢氧化物膜对锌电极可充性的影响。实验结果表明 :在锌电极表面成膜后 ,可以显著地抑制充电过程中的枝晶生长 ,又在电解液中加入枝晶抑制剂 ( CTMB) ,最后达到了令人满意的效果 ;同时 ,成膜还能有效地缓解锌电极在充放电过程中的容量损失。在整个实验过程中 ,完全去掉了传统的锌电极添加剂——有毒的汞 ,从而为研究和开发实用的环保型二次锌电极提供了一条新的途径     

煤飞灰多环芳烃环境标准参考物的研制与定值

研制了一种煤飞灰多环芳烃（ＰＡＨｓ）环境标准参考物，用高效液相色谱ＨＰＬＣ（ＵＶＤ／ＦＬＤ）作为分析方法，对其均匀性和稳定性进行了检验，对几种有代表性的ＰＡＨｓ的分析统计结果表明，其均匀性是合格的，在－２５℃保存时，稳定性在两年以上，采用两种独立可靠的方法（提取－直接进样ＨＰＬＣ和提取－硅胶柱预分离－ＨＲＧＣ），给出了煤飞灰参考物质中几种ＰＡＨ的定值结果：菲（ＰＨ）７．１±２．６μｇ／ｇ，蒽（ＡＮ     

突发性环境污染事故的分类特征及处置措施——以保定市两起危及环境安全事故为例

环境污染事故具有时间上的突发性、形式不确定性、危害的严重性和处理处置的艰巨性.发生在河北省保定市境内的两起危及水环境安全的事故具有典型性和代表性.事故发生后通过采取一系列相应的应急措施,有效地控制了大规模的环境污染;如何防止和应对突发环境污染事故,维护环境安全,已成为环境保护工作的重大新课题.面对环境安全事故及跨流域、跨区域环境污染事故的频繁发生,应从排查污染隐患、建立完善的环境应急响应体系、加强环境应急基础设施建设等方面入手,减少事故的发生,减轻对环境的危害.     

TCC/TCS对生物处理过程中微生物的抑制作用

采用细菌生长抑制法,观察了TCC/TCS对生物处理系统中厌氧菌和需氧菌生长的影响,并确定了废水中TCC/TCS对细菌影响的限量。实验结果表明,当TCC/TCS含量为40mg/L时,对需氧菌的抑制率为16.0％,含量为80mg/L时,抑制率为45％,含量640mg/L时,抑制率99.9％。TCC/TCS对厌氧菌的抑制较为敏感,含量为40mg/L时,抑制率为29.3％,含量80mg/L时,抑制率为63.0％,含量640mg/L,抑制率100％。TCC/TCS对微生物的最大无作用剂量,需氧菌为20mg/L,厌氧菌为10mg/L。吐温—80对TCC/TCS具有分解作用,当以1:3比例加入吐温—80,并使两者作用10min后,则TCC/TCS对微生物的抑制率可减少一半左右。这提示我们可利用吐温—80分解TCC/TCS,以减小TCC/TCS对微生物的抑制作用。     

水质自动监测站建设的要求与管理的思考

水环境自动监测现已是中国水环境监测的发展趋势,建设水质自动监测站前期准备工作与后来实践效果有着很大的关系,建设水质自动监测站的站址选择,采水系统工程的施工,监测仪器的选配,安装,严格遵守仪器技术要求和认真执行操作程序对监测数据的准确性有很大的相关性.现就同江水质自动监测站建站几年来运行情况,管理情况,建站时的设想及实践中联想到的问题浅谈个人点滴体会,仅供所需单位参考.     

松嫩流域特大洪灾的醒示:湿地功能的再认识

分析了１９９８年松嫩流域特大洪水发生与湿地丧失和退化的关系,根据湿地所具有的多种功能和效益,提出了松嫩流域水资源管理和防洪体系建设对策。近半个世纪以来,由于人口增长,人水争地,松嫩流域内湿地丧失达７０％,湿地质量也发生明显的退化,使本区湿地具有的抵御洪水、调节径流、蓄洪防旱、控制污染、生物多样性保护等方面功能逐渐降低,生态环境趋于恶化。必须从全流域、大系统的角度出发,全面分析上、中、下游的自然、社会、经济条件与湿地的地位,统筹规划,分步实施,封山育林,保持水土,圈地分洪,保护湿地,加固堤防,疏浚河道,整治环境,合理开发,将区域的社会、经济发展建立在可持续的环境基础上。     

喹啉及其衍生物微生物降解研究进展

喹啉类氮杂环化合物在水、土壤环境中普遍存在，受其污染的水、土壤环境生物修复是目前环境治理领域的重要课题。介绍了近年来喹啉类氮杂环化合物微生物降解的国内外研究进展，主要包括可利用喹啉类氮杂环化合物作为碳源、氮源和能源的微生物资源、微生物降解的有氧代谢和无氧代谢两大途径，以及喹啉类化合物的降解动力学。在此基础上，提出了需要进一步研究的方向。     

用改性三效催化剂净化汽车尾气的试验研究

在制备Cu-Mn-Ce-O三效催化剂的基础上，通过实验研究了制备各种催化剂的空燃比特性和温度特性，结果表明：掺杂非贵金属K、Fe和TiO2只能提高尾气中某些组分的转化率，缩小催化剂的操作窗口；贵金属Pd的加入提高了催化剂的三效活性，加宽了催化剂的操作窗口，而催化剂的起燃温度没有明显降低。     

Water quality induced corrosion of stainless steel valves during long-term service in a reverse osmosis system

The current study analyzes the contribution of 10 water quality parameters (including pH, turbidity, conductivity, total dissolved solids (TDS), hardness, total organic carbon (TOC), alkalinity, calcium ions, chlorides and sulfates) to corrosion extent of stainless steel valves taken from different locations in a reverse osmosis system of a reclaimed water plant. The valves were in service for 5 years. Raman spectroscopy and X-ray photoelectron spectroscopy analyses are conducted to quantify corrosion products on different valves under various water quality conditions. On that basis, bivariate and multivariate regression analyses between the 10 water quality parameters and the corrosion extent of valve specimens (represented by metal loss percentage (MLP) values) are carried out to check the contribution of those water quality parameters to MLP. The results indicate that the proportions of metal oxides as corrosion products vary according to the corrosion extent of the valves. Although no linear correlation is found, all 10 water quality parameters except for pH show a significant positive correlation with the MLP values of the valve specimens. Moreover, results of multivariate regression suggest that the variation of MLP can be explained by turbidity, TDS, TOC and sulfates. A positive contribution of turbidity, TDS and TOC to MLP is observed, whereas the contribution of sulfates is negative. The results from the current work help to identify the reasons for water quality-induced failure of stainless steel equipment in RO systems.     

Bioaugmentation and quorum sensing disruption as solutions to increase nitrate removal in sequencing batch reactors treating nitrate-rich wastewater

Bioaugmentation of denitrifying bacteria can serve as a promising technique to improve nutrient removal during wastewater treatment. While denitrification inhibition by bacterial quorum sensing (QS) in Pseudomonas aeruginosa has been indicated, the application of bacterial QS disruption to improve nitrate removal from wastewater has not been investigated. In this study, the effect of bioaugmentation of P. aeruginosa SD-1 on nitrate removal in sequencing batch reactors that treat nitrate rich wastewater was assessed. Additionally, the potential of a quorum sensing inhibitor (QSI) to improve denitrification following bacterial bioaugmentation was evaluated. Curcumin, a natural plant extract, was used as a QSI. The chemical oxygen demand (COD) and initial nitrate concentration of the influent were 700±20 mg/L and 200±10 mg/L respectively, and their respective concentrations in the effluent were 56.9±3.2 mg/L and 9.0±3.2 mg/L. Thus, the results revealed that bioaugmentation of P. aeruginosa SD-1 resulted in an increased nitrate removal to 82%±1%. Further, nitrate was almost completely removed following the addition of the QSI, and activities of nitrate reductase and nitrite reductase increased by 88%±2% and 74%±2% respectively. The nitrogen mass balance indicated that aerobic denitrification was employed as the main pathway for nitrogen removal in the reactors. The results imply that bioaugmentation and modulation of QS in denitrifying bacteria, through the use of a QSI, can enhance nitrate removal during wastewater treatment.