水中毒物对硝化反应毒性的快速检测

本文描述了一种利用硝化细菌快速、灵敏的检测急性毒物的方法 ,该方法将ATU作为亚硝酸细菌的选择性抑制剂 ,通过测定硝化细菌的耗氧速率来反映毒物毒性作用的大小 ,同时测定毒物的EC50 值。将本方法应用于底泥毒性检测中 ,与传统方法相比结果一致。     

黄石市夏季昼间大气PM10与PM2.5中有机碳、元素碳污染特征

2012年7月,对黄石市城区夏季昼间大气颗粒物PM10与PM2.5样品进行采集,并用热/光反射法(TOR)分析其中的有机碳(OC)、元素碳(EC).结果显示,新老城区PM10中OC平均含量分别为14.60μg·m-3和18.70μg·m-3,EC平均含量分别为4.70μg·m-3和11.02μg·m-3;PM2.5中OC平均含量分别为11.89μg·m-3和13.66μg·m-3,EC平均含量分别为2.28μg·m-3和4.96μg·m-3.研究结果表明,夏季昼间黄石市新老城区大气PM10与PM2.5中碳组分浓度变化趋势相同,且老城区大气PM10、PM2.5中的OC和EC含量普遍要比新城区高,且PM10中OC、EC在总碳(TC)的质量分数均高于在PM2.5中,说明黄石市老城区碳污染状况较新城区要严重,其夏季昼间大气粗颗粒物中碳的含量更高.通过对OC/EC及8个碳组分进行探讨,发现黄石市大气颗粒物中OC易形成二次污染,而EC排放以烟炱为主,夏季燃煤和机动车尾气是黄石碳污染的重要污染源,生物质燃烧也具有一定影响.     

武汉市城区大气PM2．5的碳组分与源解析

大气细颗粒物（PM2．5）和碳组分（OC,EC）是影响大气能见度、气候变化以及人体健康的重要污染物,研究大气颗粒物及其中碳组分的污染特征及各类典型污染源对大气细颗粒物及碳组分的贡献,对于认识区域和城市大气污染状况,控制细颗粒物的污染,具有重要意义。2011年7月至2012年2月,利用大流量PM2．5采样器采集武汉市大气细颗粒物样品并对其碳组分进行测定。武汉市城区大气中PM215、OC和EC的质量浓度平均值分别为（127±48．7）、（19．4±10．5）和（2．9±1．48）μg·m-3。其PM2．5的浓度处于我国主要城市的中等偏高水平,而OC、EC的浓度则属中等偏下水平,但均高于国外城市。武汉市大气PM2,质量浓度的季节性变化呈现出秋季〉冬季〉夏季的趋势,是气象因素和污染源排放综合影响的结果。OC浓度和EC浓度具有较好的相关性（r2=0．69）,表明二者存在来源联系。OC／EC的比值为6．7,指示武汉市大气中OC和EC的来源受汽车尾气排放和生物质燃烧的共同影响。SOA的平均质量浓度值为12．5μg·m-3约占PM2．5平均质量浓度的9．8％,表明SOA对武汉市城区大气PM2．5具有重要贡献。结合PM2．5所含的水溶性离子、微量元素组成,利用正矩阵因子分析（PMF）模型对武汉市城区大气PM2．5来源进行解析,结果表明,其主要来源及贡献率分别为机动车源（27．1％）、二次硫酸盐和硝酸盐（26．8％）、工厂排放（26．4％）和生物质燃烧（19．6％）。     

异噻唑啉酮类化合物对三角褐指藻的抑制效应

研究了不同浓度异噻唑啉酮类化合物BIT(1,2-苯并异噻唑啉-3-酮)及其类似物X(N-丙酰基-1,2-苯并异噻唑啉酮-3-酮)对三角褐指藻生长的抑制效应.根据藻细胞生长、比生长速率、藻细胞密度比、藻细胞内色素含量变化结果表明,在实验所设定的浓度(0~3mg/L)范围内,BIT和X在高浓度下对三角褐指藻生长均具有一定的抑制效应,增加细胞生长的延滞期,但在低浓度下不明显,BIT的抑制效应优于X,但BIT和X的这种抑制作用均会随着处理时间的延长而减弱,藻细胞逐渐恢复快速增殖.根据Logistic曲线方程拟合获得的BIT和X对藻的96h半效应质量浓度(EC50)分别为1.95mg/L(R2=0.988, P=0.0013)和3.26mg/L(R2=0.908, P=0.0279),EC50值的大小进一步说明BIT比X对三角褐指藻的抑制作用强.     

Persistence of chlorpyriphos in okra (Abelmoschus Esculentus) fruits and soil

Persistence of cypermethrin and chlorpyriphos in okra and soil were studied following the application of pre-mix formulation of insecticides Action 505EC (chlorpyriphos 50%?+?cypermethrin 5%) at single (275?g a.i.?ha^?1) and double dose (550?g a.i.?ha^?1). The average initial deposits of chlorpyriphos in okra were observed to be 0.07 and 0.15?mg?kg^?1 in single and double dose, respectively, which dissipated to 92% after 10 days for both the dosages. Residues of soil under okra crop were found to be 0.15?mg?kg^?1 at the single and 0.36?mg?kg^?1 at the double doses. These residues persisted up to 3 days at single and 5 days at double dose. The half-life (t _1/2) periods of chlorpyriphos on okra and soil were observed to be 0.6 days and 1.9 days for single and double dose, respectively. Residues of chlorpyriphos reached below detectable level (BDL) of 0.01?mg?kg^?1 in okra fruits after 7 days at single dose and in 15 days in double dose. In soil, residues of chlopyriphos persisted up to 5 and 7 days in single and double dose, respectively. Following foliar applications of a insecticide formulation (Action 505EC, (chlorpyriphos 50%?+?cypermethrin 5%) on okra at @ 275 and 550?g active ingredient (a.i.)?ha^?1 resulting in active applications of chlorpyriphos at the rate of 250 and 500?g a.i.?ha^?1 the average initial deposits of chlorpyriphos in okra were observed to be 0.07 and 0.15?mg?kg^?1, respectively. These residue levels dissipated to 92% after 10 days at both the dosages. Residues of soil under the okra crop were found to be 15?mg?kg^?1 at the single and 36?mg?kg^?1 at the double dose. The residues persisted up to 3 days at the single and 5 days at the double dose. The half-life (t _1/2) periods of chlorpyriphos on okra were observed to be 0.6 days for application rates, and 1.9 days for soil. Okra fruits and soil samples collected on the 7th and 15th day after application did not show any chlorpyriphos residues above their determination limits of 0.01 and 0.005?mg?kg^?1, respectively.     

山西煤层自燃区PM10中有机碳、元素碳的特征

采集了山西大同市、宁武县和河曲县煤层自燃区12个点位PM10样品,采用Analysensysteme GmbH Vario E1型元素分析仪分析了PM10中有机碳(OC)和元素碳(EC)组分,探讨了煤层自燃区OC、EC污染特征、总碳气溶胶(TCA)对PM10的贡献、OC/EC比值.结果表明, PM10、OC、EC的质量浓度范围分别为114~401,22.9~68.1,21.9~70.7μg/m3.不同区域PM10、OC和EC污染水平差异较大,河曲县PM10污染最为严重,宁武县碳污染水平最高.露头煤层自燃区PM10低于采空自燃区,而对于OC和EC则相反.TCA对PM10的贡献高达63.82%,且露头煤层自燃区TCA对PM10的贡献比采空自燃区高.不同采样点OC/EC值介于0.7～1.6之间,小于前人结论中相似源OC/EC值.二次有机碳( SOC)污染较小.     

利用概率单位法估算EC50的研究（Estimation of Probit Methods on EC50）

以两组典型毒性数据为例,综合比较了5种常见概率单位模型计算程序在EC50估算上的差异,并在此基础上比较了3种不同置信区间的估算方法.在对照组受抑制率为零时,5种方法的参数估算结果一致;当对照组受抑制率不为零时,将对照组数据纳入整个计算过程的方法可以给出可靠的参数估算结果.3种不同置信区间估算方法的比较表明:在毒性数据分布对称性良好的情况下,基于Delta函数与Fieller定理的方法给出的结果相近,但后者可以在更广泛的情况下给出置信区间;相比而言,基于bootstrap重抽样的非参数方法获得的置信区间较窄,表现出更好的灵敏度.     

Measurement of machinery safety level in the European market: A real case based on market surveillance data

This article aims to highlight the current status of compliance to Machinery Directive 98/37/EC (transposed to Spanish regulation as RD 56/1995, of 20th January) (a new directive numbered as 2006/42/EC [Directive 2006/42/EC of the European Parliament and of the Council of 17 may 2006 on machinery, and amending Directive 95/16/EC (recast). OJ L157/24-86, 9.6.2006.], that recasts and replaced 98/37/ED directive and its amendments, came into force on 29 June 2006; it will not be applied until 29th December 2009. European Member States have a lead-time of two years to adopt and publish the national laws and regulations transposing the provisions of the new Directive into national law. Latest 10th October, Spain transposed Machinery Directive 2006/42/EC to national regulation as Real Decreto 1644/2008 [Real Decreto 1644/2008, de 10 de octubre, por el que se establecen las normas para la comercialización y puesta en servicio de las máquinas. BOE 246/2008, de 11 octubre 2008. Páginas 40995–41030]) of a particular family of machinery (hand-held, medium and small-size, deeply introduced in the market, of low-medium cost), that any user, professional or non-professional, can acquire as first-hand in any of the sales points (whether or not experts in these kind of products).At the same time, it emphasises the most significant shortcomings and non-conformities found, after analyzing the results of five consecutive Campaigns of Control of Industrial Products performed by one of the labs (placed in Spain) involved in the market surveillance European Program.     

外循环厌氧反应器接种好氧污泥的启动研究

内蒙古自治区某啤酒厂的外循环厌氧反应器完成了首次启动后由于操作问题,导致系统运行崩溃.第2次接种后续生物接触氧化池的好氧污泥进行重新启动,经过20 d的驯化,好氧污泥转变为活性较高的厌氧污泥;采用低负荷高去除率的方式运行40 d后,塔内形成了部分颗粒污泥;之后,为了提高颗粒污泥量快速提高进水流量,COD去除率先突然下降然后缓慢升高.当进水流量达到最大时启动结束,此时塔内颗粒污泥量和COD去除率仍在缓慢上升.     

Contents and sources of DDT impurities in dicofol formulations in Turkey

Background, aim, and scope  Dicofol is widely used as a pesticide in agriculture applications. Since dicofol is mainly synthesized from dichlorodiphenyltrichlorethane (DDT), it contains DDT as an impurity. The European Community has forced Prohibition Directive 79/117/EEC to reduce DDT in dicofol formulations. Specifically, DDT content in a dicofol formulation cannot exceed 0.1%. The goal of this project was to determine the DDT content in dicofol formulations used in Turkey. Materials and methods  Samples of all the dicofol formulations in Turkey were collected to quantify DDT and DDT-related compounds. Four replicates were used for each sample. GC/MS/MS was used to analyze p,p′ and o,p′ isomers of DDT, DDD, and DDE. A HPLC was used to determine p,p′-Cl-DDT concentrations. Results  The total DDT content of the formulated dicofol was found between 0.3% and 14.3%. The concentration of p,p′-DDE ranged from 167 to 1,042 mg kg⁻¹ in dicofol samples. p,p′-DDT concentrations were found to be 32 to 183 mg kg⁻¹. The o,p’-DDT level ranged from 2 to 34 mg kg⁻¹ in the dicofol formulations analyzed. Discussion  It was estimated that 617.8 kg of DDT was released from dicofol. The main impurity was identified as p,p-Cl-DDT. Based on these results, dicofol serves as a continuing source of DDT contamination. Conclusions  All DDT concentrations in dicofol samples analyzed were higher than the permitted 0.1% level of Prohibition Directive 79/117/EEC. The reduction of dicofol is critical since it serves as a continual source of DDT contamination. Recommendations and perspectives  DDT has been found in soil, water, and air samples. Dicofol has been identified as a contributor to continued DDT contamination in soil and water. More studies are needed to ascertain the source of DDT in the air.