气相色谱法测定柑橘和土壤中螺螨酯残留

以丙酮为提取剂,二氯甲烷为萃取剂,采用弗罗里硅土柱净化,气相色谱-电子捕获检测器测定柑橘和土壤中的螺螨酯残留,优化了样品前处理条件。方法在0.141μg/L～5.65 mg/L范围内线性良好,最低检出限为0.003 5 mg/kg,空白样品在0.050 mg/kg、0.500 mg/kg、1.00 mg/kg 3个添加水平上的平均回收率为82.2%～110%,平行测定的RSD为2.6%～9.8%。     

高效液相色谱法测定柑橘及橘园土壤中乙撑硫脲残留

建立了高效液相色谱测定柑橘及橘园土壤中乙撑硫脲残留的方法,优化了试验条件.方法在0 mg/L～5.35 mg/L范围内线性良好,橘园土壤、橘皮、橘肉样品的检出限(以鲜重计)分别为0.006 mg/kg、0.008 mg/kg、0.006 mg/kg,样品测定的RSD≤5.1%,加标回收率为82.9%～92.8%.     

污染土壤中六价铬的测定

通过加入碱性消解液、MgCl2和磷酸缓冲溶液,建立了污染土壤中六价铬的分光光度测定法.方法在0 mg/L～0.200 mg/L范围内线性良好,检出限为0.16 mg/kg(以2.5 g样品计),土壤样品测定的RSD为4.6%,加标回收率为92.3%～107%.     

超声波萃取-红外分光光度法测定土壤中石油类

采用超声波萃取-红外分光光度法测定土壤中石油类,并对超声波机的功率、水浴温度和萃取时间进行优化.试验表明：方法在0mg/L～80.0mg/L范围内线性良好,相关系数r为0.9997;方法检出限为6.00μg/L,当取土壤样品10.0g时,方法检出限为0.03mg/kg;空白土壤的加标回收率为97.4% ～103%;测定实际土壤样品的RSD为3.0% ～3.9%.通过比较超声波萃取、四氯化碳热浸法和快速溶剂萃取法的前处理效果,显示出超声波萃取法的优越性.     

气相色谱法测定土壤中菊酯类农药残留

以正己烷/丙酮混合溶剂(体积比为1∶1)为提取剂,采用Florisil柱净化、气相色谱电子捕获检测器测定土壤中菊酯类农药残留,优化了提取条件。4种菊酯类农药在0.010 mg/L~1.00 mg/L范围内线性良好,方法检出限为0.005 mg/L~0.010 mg/L,甲氰菊酯回收率为85.2%~103%,RSD为2.3%~5.4%;氯氰菊酯回收率为80.5%~103%,RSD为2.8%~6.7%;氰戊菊酯回收率为80.2%~103%,RSD为2.3%~6.0%;溴氰菊酯回收率为80.8%~103%,RSD为2.4%~6.2%。     

顶空气相色谱法快速测定土壤中苯、苯胺和硝基苯

采用顶空气相色谱法快速测定土壤中苯、苯胺和硝基苯,优化了试验条件.方法在0 mg/L～100 mg/L范围内线性良好,苯、苯胺、硝基苯的检出限分别为0.012 mg/kg、0.22 mg/kg、0.083 mg/kg,实际土样测定的RSD≤1.4%,加标回收率为94.0%～102%.     

GC- M S法测定蔬菜和水果中八氯二丙醚

建立了固相萃取-GC-MS法测定蔬菜和水果中八氯二丙醚残留的方法,样品采用乙腈均质提取,固相萃取柱净化,正己烷定容.优化了试验条件,选择了定性与定量离子,方法线性良好,最低检出限为0.004 7 mg/kg,加标量为0.10 mg/L～1.00 mg/L时,回收率为87.0%～96.0%,RSD＜4.0%.     

ASE-气相色谱法测定油田区土壤中多种石油烃

采用气相色谱法测定油田区土壤中C_(10)～C_(40)的石油烃,通过优化加速溶剂萃取的条件,使方法在62 mg/L～3 100 mg/L范围内线性良好,方法检出限为4.8 mg/kg。用该方法测定石油区短期、中期、长期油井污染土壤样品,5次测定结果的RSD为1.3%～5.2%,加标回收率为84.8%～98.5%,有证标准样品测定结果在可信区间内。     

加压溶剂萃取/气相色谱-质谱法测定土壤中的三嗪类农药

建立了加压溶剂萃取/气相色谱-质谱法,用于测定土壤中的10种三嗪类农药。以正己烷-丙酮(体积比1∶1)为萃取剂,对土壤样品进行加压溶剂萃取。将提取液净化浓缩后,采用气相色谱-质谱联用仪进行检测,根据保留时间和特征离子定性,内标法定量。10种三嗪类农药在0.05～5 mg/L范围内的线性关系良好(相关系数≥0.997),检出限为0.002～0.003 mg/kg。对实际土壤样品进行高、中、低浓度加标,测得的回收率范围为66.7%～102%,相对标准偏差范围为0.79%～5.49%。该方法简便可靠、灵敏度高,适用于土壤中三嗪类农药的测定。     

SPE- GC/MS法测定水中对硝基氯苯和2,4- 二硝基氯苯

采用SPE-GC/MS法测定水中对硝基氯苯和2,4-二硝基氯苯,优化了试验条件.对硝基氯苯在1.00 mg/L～80.0 mg/L之间线性关系良好,2,4-二硝基氯苯在1.00 mg/L～50.0 mg/L之间线性关系良好,方法检出限对硝基氯苯为0.6 μg/L,2,4-二硝基氯苯为2.1 μg/L,回收率对硝基氯苯为86.2%～94.7%,2,4-二硝基氯苯为87.3%～95.4%.     

高效液相色谱法测定稻田中丙草胺残留

用二氯甲烷提取稻田水和水稻植株样品中的丙草胺，稻田土壤样品用二氯甲烷-甲醇混合溶剂（体积比为9∶1）提取，再用高效液相色谱仪测定。方法在0．02 mg/L～2．00 mg/L的范围内线性良好，相关系数为0．9998；稻田水、土壤，水稻植株中丙草胺的检出限分别为0．001 mg/L、0．005 mg/kg、0．01 mg/kg；对稻田水、土壤和水稻植株分别做3个浓度水平的加标回收试验，重复5次，平均回收率在75．5％～84．7％之间，测定结果的相对标准偏差为2．0％～10．5％。     

程序控温石墨消解-原子荧光法测定土壤中总砷

采用程序控温石墨全自动消解仪消解土壤样品，原子荧光光谱法测定总砷。通过试验确定原子荧光光度计的最佳工作条件，使得该方法在2.00μg／L ～20.0μg／L 范围内线性良好，检出限为0.025 mg／kg，加标回收率在96.0％～10^5％之间，RSD为1.9％～3.3％。用该方法与国标法同时测定土壤标准样品和实际样品，结果无显著差异。     

ASE萃取-GPC净化-HPLC法测定土壤中阿特拉津

以二氯甲烷-丙酮（体积比1∶1）为混合溶剂，用加速溶剂萃取仪萃取土壤样品中的阿特拉津，提取液通过凝胶渗透色谱净化，用高效液相色谱仪在220 nm波长下测定，试验表明，在0．05 mg/L～5．00 mg/L范围内线性良好。方法检出限为0．22μg/kg，对空白土壤进行加标回收，平行测定6次，平均回收率为88．2％～102％，RSD为4．5％～7．6％，符合农药残留分析的要求。     

沧州地区氟元素在不同介质中的分布

以沧州地区的地下水、土壤和小麦中的氟元素为研究对象,探讨氟元素在地下水、土壤和小麦等不同介质中的含量、空间分布与来源成因。通过绘制各介质中氟元素分布图,获得氟元素在各介质中不同深度的含量及水平空间上的分布特征。结果显示,当地深层地下水氟含量平均为2.25 mg/L,高于浅层地下水的平均值0.80 mg/L;深层和浅层土壤氟含量接近,平均值分别为557.18、569.20 mg/kg;小麦中的氟含量最高值为0.96 mg/kg,当地小麦氟含量均低于国家标准限值(1.0 mg/kg)。根据氟元素的分布特点分析,当地深层地下水与土壤的氟元素来源一致,而不同于浅层地下水中的氟;小麦的氟元素分布受浅层土壤氟影响较大。     

高效液相色谱法测定土壤中三嗪类除草剂

建立了索氏提取、中性氧化铝小柱净化、高效液相色谱二极管阵列检测器测定土壤中7种三嗪类除草剂的方法，优化了检测波长、提取方法和溶剂、梯度淋洗程序等试验条件。7种三嗪类除草剂在0．10mg／L～2．00mg／L范围内线性良好，检出限为0．84μg／kg～2．07μg／kg，RSD为1．2％～5．6％，加标回收率为95.0％～107％。     

Assessment of phenol infiltration resilience in soil media by HYDRUS-1D transport model for a waste discharge site

The movement of contaminants through soil imparts a variety of geo-environmental problem inclusive of lithospheric pollution. Near-surface aquifers are often vulnerable to contamination from surface source if overlying soil possesses poor resilience or contaminant attenuation capacity. The prediction of contaminant transport through soil is urged to protect groundwater from sources of pollutants. Using field simulation through column experiments and mathematical modeling like HYDRUS-1D, assessment of soil resilience and movement of contaminants through the subsurface to reach aquifers can be predicted. An outfall site of effluents of a coke oven plant comprising of alarming concentration of phenol (4–12.2 mg/L) have been considered for studying groundwater condition and quality, in situ soil characterization, and effluent characterization. Hydrogeological feature suggests the presence of near-surface aquifers at the effluent discharge site. Analysis of groundwater of nearby locality reveals the phenol concentration (0.11–0.75 mg/L) exceeded the prescribed limit of WHO specification (0.002 mg/L). The in situ soil, used in column experiment, possess higher saturated hydraulic conductivity (K _S ?=?5.25?×?10^?4 cm/s). The soil containing 47 % silt, 11 % clay, and 1.54 % organic carbon content was found to be a poor absorber of phenol (24 mg/kg). The linear phenol adsorption isotherm model showed the best fit (R ²?=?0.977, RMSE?=?1.057) to the test results. Column experiments revealed that the phenol removal percent and the length of the mass transfer zone increased with increasing bed heights. The overall phenol adsorption efficiency was found to be 42–49 %. Breakthrough curves (BTCs) predicted by HYDRUS-1D model appears to be close fitting with the BTCs derived from the column experiments. The phenol BTC predicted by the HYDRUS-1D model for 1.2 m depth subsurface soil, i.e., up to the depth of groundwater in the study area, showed that the exhaustion point was reached within 12 days of elapsed time. This clearly demonstrated poor attenuation capacity of the soil to retard migration of phenol to the groundwater from the surface outfall site. Suitable liner, based on these data, may be designed to inhibit subsurface transport of phenol and thereby to protect precious groundwater from contamination.     

Metal immobilization and phosphorus leaching after stabilization of pyrite ash contaminated soil by phosphate amendments

In this study we would like to show the importance of a holistic approach to evaluation of chemical stabilization using phosphate amendments. An extensive evaluation of metal stabilization in contaminated soil and an evaluation of the leaching of phosphorus induced after treatment were performed. The soil was highly contaminated with Cu (2894 mg kg(-1)), Zn (3884 mg kg(-1)), As (247 mg kg(-1)), Cd (12.6 mg kg(-1)) and Pb (3154 mg kg(-1)). To immobilize the metals, mixtures of soil with phosphate (from H(3)PO(4) and hydroxyapatite (HA) with varying ratios) were prepared with a constant Pb : P molar ratio of 1: 10. The acetic acid extractable concentration of Pb in the mixture with the highest amount of added phosphoric acid (n(H(3)PO(4)) : n(HA) = 3 : 1) was reduced to 1.9% (0.62 mg L(-1)) of the extractable Pb concentration in the untreated soil, but the content of water extractable phosphorus in the samples increased from 0.04 mg L(-1) in the untreated soil sample up to 14.3 mg L(-1) in the same n(H(3)PO(4)) : n(HA) = 3 : 1 mixture. The high increase in arsenic mobility was also observed after phosphate addition. The PBET test showed phosphate induced reduction in Pb bioavailability. In attempting to stabilize Pb in the soil with the minimum treatment-induced leaching of phosphorus, it was found that a mixture of soil with phosphate addition in the molar ratio of H(3)PO(4) : HA of 0.75 : 1 showed the most promising results, with an acetic acid extractable Pb concentration of 1.35 mg L(-1) and a water extractable phosphorus concentration of 1.76 mg L(-1). The time-dependent leaching characteristics of metals and phosphorus for this mixture were evaluated by a column experiment, where irrigation of the soil mixture with the average annual amount of precipitation in Slovenia (1000 mm) was simulated. The phosphorus concentration in the leachates decreased from 2.60 mg L(-1) at the beginning of irrigation to 1.00 mg L(-1) at the end.     

黑龙江省松花江流域河流中高锰酸盐指数非点源污染负荷分析

采用3种方法分析黑龙江省松花江流域高锰酸盐指数非点源污染的负荷。分析结果显示,非点源污染造成的松花江流域高锰酸盐指数负荷约为70%;松花江流域支流源头属于高高锰酸盐指数河段,本底值约为5mg/L,河流流经1000Km非点源污染会增加高锰酸盐指数约1mg/L;松花江流域河流中高锰酸盐指数含量高的主要原因是流域内土壤有机质含量高。     

全自动石墨消解-原子荧光法测定土壤总汞

采用全自动石墨消解-原子荧光光度法对土壤总汞进行测定,确定最佳消解时间为1 h,消解液最佳用量为8.0 m L。方法在总汞质量浓度为0.2~2.0μg/L范围内具有良好的线性,相关系数为0.999 9,当取样量为0.500 0 g时,检出限为0.002 mg/kg;测定不同标准土壤样品总汞的结果均在保证值范围内,精密度为4.0%~7.0%,加标回收率为95.0%~108.5%;对甘肃省实际土壤及沉积物样品测定进一步验证了方法的适用性。该法适合大批量样品分析,对于提高工作效率有重要意义。