液液萃取-气相色谱法测定地表水中17种有机氯农药研究

建立了二氯甲烷液液萃取-气相色谱法同时测定地表水中17种有机氯农药的方法。标准曲线线性良好,17种化合物的相关系数R2均大于0.999。当取样量为200 mL时,方法检出限在0.015μg/L~0.062μg/L之间。以超纯水样品进行基质加标实验,重复测定6次的相对标准偏差为1.2%~6.2%,平均加标回收率为72.8%~93.5%。方法简单快捷,精密度良好,准确性高,适用于地表水中痕量有机氯农药的测定。     

粤桂水源地有机氯农药的污染特征及生态风险

利用固相萃取-气相色谱-质谱联用技术(SPE-GC-MS)检测了粤桂水源地7个采样点水样中16种有机氯农药(OCPs)的浓度,分析了研究区OCPs的污染特征;利用BurrⅢ型分布构建了8种OCPs的物种敏感度分布曲线,并计算出不同OCPs对淡水水生生物的HC5(hazardous concentration for 5%species)值,最后应用安全阈值法评价了OCPs对水生生物的生态风险.结果表明,OCPs的浓度在6.64~34.19 ng·L~(-1)之间,平均值为16.76 ng·L~(-1),HCHs和DDTs及其降解产物在污染物中的贡献比例较大.HCHs主要来自家庭杀虫剂中的林丹,DDTs主要来自三氯杀螨醇的污染或历史残留.脊椎动物对OCPs的耐受性高于无脊椎动物,α-硫丹对水生植物和微生物的影响较大,p,p'-DDT对脊椎动物和无脊椎动物的影响较大.粤桂水源地OCPs对水生生物没有显著的生态风险,但DDTs和α-硫丹对水生生物存在较高的潜在风险,应加以重视.     

广州南沙红树林湿地水体和沉积物中有机氯农药的残留特征

红树林湿地对保护海岸生态环境起着重要作用,为研究有机氯农药(OCPs)在广州南沙红树林湿地水体和沉积物中的残留水平、来源和生态风险,于2015年3月采集该地区10个表层水体样品和7个表层沉积物样品,并采用GC-ECD测定其中OCPs的含量.结果表明,水体中OCPs含量为1.89~90.19 ng·L~(-1),平均值为30.16 ng·L~(-1);沉积物中OCPs含量为3.10~16.02 ng·g~(-1),平均值为8.58 ng·g~(-1).与其他河口、海湾地区相比,研究区有机氯农药污染处于中等水平.研究区水体和沉积物间HCHs和DDTs的分配系数平均值分别为857和368;在分配系数较高的区域,沉积物成为水体二次污染源的潜力较大.来源分析表明,研究区水体和沉积物中近期仍存在HCHs和DDTs输入,HCHs主要来源于林丹的使用,DDTs来源于三氯杀螨醇与工业DDT的混合输入;与水体相比,沉积物中的OCPs可能包含更多历史残留组分.风险评价结果显示,水体中OCPs的生态风险较小,但沉积物中OCPs存在较高的生态风险,可能危害红树林生态系统.     

江汉平原典型土壤环境中有机磷农药的分布特征及影响因素

为了研究江汉平原土壤中有机磷农药（OPPs）的分布特征,项目组于2015年9月在地下水监测场所在区域,采集了78个剖面土和7个表层土土样,通过气相色谱-氮磷检测器（GC-NPD）分析OPPs的含量,研究江汉平原土壤中OPPs的分布特征.结果表明,研究区土壤普遍存在OPPs,其中地表土中OPPs的含量范围为89.80~193.85 ng·g^-1,平均值为140.05 ng·g^-1;剖面土中OPPs的整体含量范围为19.81~138.28 ng·g^-1,平均值为40.99 ng·g^-1.地表土和剖面土中OPPs主要检出成分均为甲胺磷、氧化乐果、二嗪农和喹硫磷等,并且根据美国土壤农药残留限量标准,研究区土壤中10种OPPs的残留量已对农产品的安全构成威胁.研究区剖面土中∑OPPs分布为：水平方向,沿河农田剖面土 > 沿河非农田剖面土 > 中部农田剖面土,即：GS1-1 > GS4 > GS2 > GS3;垂直方向,大部分剖面土随着深度的增加整体上呈先减小后增大的趋势;研究区土壤中OPPs的分布受多种因素的影响：农业生产过程中施用OPPs的量、土壤对OPPs的吸附、解吸附作用、地下水的垂直运动、研究区的地形环境、土壤有机质的含量等.     

Monitoring and Assessment of Persistent Organochlorine Residues in Sediments from the Daliaohe River Watershed, Northeast of China

Surface sediment samples from 12 sites of the three selected rivers in Daliaohe River watershed (Hunhe River, Taizihe River and Daliaohe River) were analyzed with the objective of establishing sources and hazard of the organochlorinae pesticides (OCPs) and polychlorinated biphenyl (PCBs) in surface sediments. The total concentrations of OCPs varied from 3.06 to 23.24 ng g⁻¹. ∑HCH (α-HCH, β-HCH, δ-HCH, γ-HCH), ∑DDT (p, p′-DDE, p, p′-DDD, o, p′-DDT, p, p′-DDT) and ∑Cyclodiene (Heptachlor, Aldrin, Heptachlor epoxide, Dieldrin, Endrin) ranged from 1.86 to 21.48, 0.5 to 2.81 and 0.56 to 1.53 ng g⁻¹, respectively. Results of OCPs also illustrate that the most dominant pollutants among the OCPs was ∑HCH, and γ-HCH was the most dominant isomer in HCH, which was evidence of recent input of lindane. It possibly came from the runoff of polluted soils and long-scale transportation. Total PCB concentrations ranged between 1.88 and 16.88 ng g⁻¹. The peak concentrations of PCBs were found in sediments from station T5 and D3, which are in the vicinity of industrial areas and ferry, respectively. These data show a moderate level of OCPs and PCBs contaminations compared to that in other countries.     

Principal component analysis for soil contamination with organochlorine compounds

In order to investigate the distribution pattern of individual organochlorine compounds in soil samples collected from the sites (Canary Island – Spain, China, Germany, India, Romania, Russia, Serbia, Swiss, UK) affected by industrial activities to the more remote areas, principal component analysis was performed on the data taken from literature. Loading plots pointed out the strong correlation among the variables. Score plots revealed similar PCB- and OCP-soil patterns for majority of the investigated sites. Nevertheless, the temporal differences of PCB-soil loads have been identified: the late 1990s and early 2000s concentrations are similar to those of the early 1940s, and they are below the levels existed in 1980. The most pronounced PCB concentrations characterized the soil from 1966. For OCPs the influence of sites location on the detected concentration has been revealed: China and India were characterized by comparably higher loads of DDX (DDT and its metabolites) and of HCH-isomers, respectively.     

Pesticide Residues in Bovine Milk from a Predominantly Agricultural State of Haryana, India

One hundred forty seven samples of bovine milk were collected from 14 districts of Haryana, India during December 1998–February 1999 and analysed for the presence of organochlorine pesticide (OCPs) residues. ∑HCH, ∑DDT, ∑endosulfan and aldrin were detected in 100%, 97%, 43% and 12% samples and with mean values of 0.0292, 0.0367, 0.0022 and 0.0036 μg/ml, respectively. Eight percent samples exceeded the maximum residue limit (MRL) of 0.10 mg/kg as recommended by WHO for ∑HCH, 4% samples of 0.05 mg/kg for α-HCH, 5% samples of 0.01 mg/kg for γ-HCH, 26% samples of 0.02 mg/kg for β-HCH as recommended by PFAA and 24% samples of 0.05 mg/kg as recommended by FAO for ∑DDT. Concentrations of β-HCH and p,p′-DDE were more as compared to other isomers and metabolites of HCH and DDT.     

寡糖类农药的研制

葡萄寡糖、半乳糖醛酸寡糖、几丁质寡糖是常见的、能激活植物自卫系统的激活剂,本文综述了这几类寡糖的结构、活性、制备方法、这些寡糖会为无毒、无公害的新农药。     

气相色谱法测定土壤中37种有机磷农药残留

采用气相色谱法测定土壤中37种有机磷农药,当取样量为10 g时,37种有机磷农药方法检出限为0. 002～0. 015 mg/kg,测定下限为0. 008～0. 060 mg/kg。低含量加标样品中有机磷农药的加标回收率为72. 8%～104%,相对标准偏差为4. 2%～13. 8%;中含量加标样品中有机磷农药的加标回收率为71. 5%～101%,相对标准偏差为4. 3%～13. 5%;高含量加标样品中有机磷农药的加标回收率为74. 6%～109%,相对标准偏差为6. 8%～14. 6%。该方法灵敏度高、分离效果好、重现性好,能够满足土壤中37种有机磷农药残留检测的要求。     

SMBBR-AF-SMBBR组合工艺处理高氨氮农药废水

采用特异性移动床生物膜反应器(SMBBR)和厌氧生物滤池(AF)组合工艺处理高氨氮农药废水。考察了HRT、pH和DO等工艺条件对SMBBR-AF-SMBBR组合工艺运行稳定期COD和氨氮去除率的影响。试验结果表明,在进水COD为2 408~7 440 mg/L、ρ(NH_4~+-N)为160.21~433.84 mg/L、TN为208.27~537.65 mg/L、HRT为8d、pH为8.0、DO为4 mg/L的条件下,处理后出水平均COD为342 mg/L,COD去除率达92.3%;ρ(NH_4~+-N)小于4.0mg/L,氨氮平均去除率为89.2%;TN小于50 mg/L,平均TN去除达83.0%。出水各指标均优于原A2O工艺出水。