Residue analysis and dissipation of monosulfuron in soil and wheat

HPLC-UV residue analytical method for monosulfuron [N-[( 4' -methyl) pyrimidin- 2' -yl]-2-nitrophenylsulfonyl urea] in soil and wheat was developed. Monosulfuron residues were recovered by solvent extraction, followed by liquid-liquid partition, and C 18 cartrige clean-up. Excellent method recoveries ranging from 95%—104% for both fortified soil and wheat grain were obtained with coefficients of variation 1.5%—11.8%. The minimum detectable quantities in soil and wheat were both 4 ng, the limit of detection was 0.02 mg/kg. When monosulfuron was applied according to double dosage of maximum recommended use direction(120 g ai/hm 2 of 10% monosulfuron wettable powder sprayed for once during development of wheat) in field studies conducted in Shandong Province and near Beijing, monosulfuron residues was not detected in soil and wheat samples collected 75 d after application. Laboratory soil degradation studies showed that monosulfuron degraded faster in acidic soil and strong alkaline soil than in neutral or weak alkaline soil. Half lives in Jiangxi soil, Shijiazhuang soil, Jiangsu soil and Heilongjiang soil were 41, 48, 87 and 84 d respectively. Monosulfuron residues dissipated rapidly in Shandong and Beijing field test sites with half-lives of less than 14 d.

Economics of Residues Incorporation and Phosphorus Application for Direct Seeded Rice and Wheat under Saline Soil

Two-year long field study was conducted using a permanent layout to investigate the economics of crop residues incorporation (2 t&middotha-1) and P application (0, 40, 80 and 120 kg P2O5 ha-1) to directly sowing of rice and wheat crops gown under naturally salt-affected calcareous soil (ECe = 4.59 dS m-1;pHs = 8.38;SAR = 6.57 (mmolc L-1)1/2;CaCO3 = 3.21%;Extractable P = 4.07 mg&middotkg-1;sandy clay loam) at farmers field in district Hafizabad during the year 2012-13. Split plot design (crop residues in main plots and P application in sub plots) was followed with three replications. Agronomic data on growth and yield were collected at the time of each crop maturity. Maximum growth and yield of both the crops were harvested from the plots where P2O5 was applied @ 80 kg&middotha-1 along with crop residues incorporation. On an average of two years, maximum paddy (3.26 t&middotha-1) and wheat grain (3.56 t&middotha-1) yield were produced with P application @ 80 kg P2O5 ha-1 along with crop residues incorporation. Although, the yield harvested with this treatment (80 kg P2O5 ha-1 + crop residues) performed statistically equal to 120 kg P2O5 ha-1 without crop residues incorporation during both the years, however, on an average of two years, grain yield of directly sowing rice and subsequent wheat was significantly superior (22% and 24% respectively) than that of higher P rate (120 kg&middotha-1) without crop residues. Overall, continuous two-year crop residues incorporation further increased (17%) paddy yields during the follow up year of crop harvest. Economic analyses of both the crops were carried out to choose the best treatment with adequate economic benefits as compared to those without crop residue incorporation. Maximum net benefit of Rs = 108,680/- for direct seeded rice and Rs = 99,362/- for wheat grown with 80 kg P2O5 ha-1 application under crop residues incorporation was determined. Among P application treatments without crop residues incorporation, the maximum net benefit (Rs = 75,874/- and Rs = 65,725/-) and highest residual values (49,809 and 39,160) for direct seeded rice and wheat respectively, were obtained with extended P application rate (120 kg P2O5 ha-1) which was not again as much as that of 80 kg P2O5 ha-1 application with crop residues incorporation.

苏中地区小麦籽粒和土壤中有机磷农药残留分析

2003年在江苏省苏中地区7个县(市)分别选择具有代表性的高、中、低3种不同施药水平田块,对小麦籽粒和土壤中7种有机磷农药残留进行检测。结果表明:小麦籽粒和土壤有机磷农药检出率分别为95.2%和100%,农药残留现象比较普遍;中等毒性有机磷农药毒死蜱和乐果在苏中地区普遍存在;小麦籽粒中7种有机磷农药平均浓度均不超标,对建立无公害优质专用小麦生产体系有一定基础。

氯氟吡氧乙酸在小麦和土壤中的检测方法及其残留动态

为了解氯氟吡氧乙酸在小麦和土壤中的消解动态及其残留状况,建立了氯氟吡氧乙酸在小麦和土壤中的液相色谱分析方法,并在天津、山东和江苏三地开展了氯氟吡氧乙酸在小麦和土壤中残留田间试验研究.结果表明,采用乙酸乙酯和10%H3PO4(含4%KC l)振荡提取小麦和土壤中的氯氟吡氧乙酸,氯仿萃取,弗罗里硅土固相萃取柱净化,乙醚/石油醚(体积比为3∶97)混合液洗脱,减压浓缩,N2吹干,乙腈定容,液相色谱仪带二极管阵列检测器(DAD)进行测定,小麦植株、籽粒和土壤中氯氟吡氧乙酸的添加回收率分别为91.3%—100.2%、82.0%—90.9%和81.0%—99.7%,变异系数分别为3.2%—8.7%、3.1%—9.6%和3.1%—5.3%;氯氟吡氧乙酸在小麦和土壤中的最小检出量为3.57×10-10g,最低检出浓度为0.005 m.gkg-1.在小麦苗期喷雾施用19%苯磺隆.氯氟吡氧乙酸可湿性粉剂,氯氟吡氧乙酸在小麦植株和土壤中的残留消解动态规律符合方程Ct=C0e-kt,消解半衰期分别为7.22—9.65 d和7.99—9.92 d.在小麦芽后茎叶期喷雾施用19%苯磺隆.氯氟吡氧乙酸可湿性粉剂1次,其制剂施用量为0.06—0.09.gm-2,在小麦收获时,氯氟吡氧乙酸在小麦籽粒中的残留量均低于方法最低检出浓度.表明按推荐剂量和1.5倍在小麦芽后茎叶期喷雾施用19%苯磺隆.氯氟吡氧乙酸可湿性粉剂1次,氯氟吡氧乙酸在小麦籽粒上的残留是安全的.

单嘧磺隆在小麦田中的残留试验研究

研究了单嘧磺隆的残留分析方法 ,单嘧磺隆在土壤中的消解动态和在土壤、小麦中的最终残留 .土壤经甲醇 /氨水混合液提取 (小麦用丙酮 /水混合液 ) .液液分配及C1 8小柱净化、用带紫外检测器的高效液相色谱仪测定 .单嘧磺隆的最低检出量为 4ng ,在土壤和小麦中的最低检出浓度为 0 0 2mg·kg- 1 .本方法的平均添加回收率为 91 1 7— 1 0 3 8% ,变异系数为 1 47— 1 1 8% .应用上述方法 ,测定了单嘧磺隆在北京、山东两地土壤中的消解动态以及在土壤、小麦中的最终残留 .结果表明 :在北京土壤中的半衰期为 9 2 4d ;在山东土壤中的半衰期为 1 3 5 9d;当按推荐剂量施药 ,小麦收获时 ,在土壤和小麦中 ,北京。

苯达嗪丙酯在土壤和小麦中的田间残留试验

建立了土壤和小麦种子、茎杆中苯达嗪丙酯的残留分析方法.研究了高剂量施药条件下土壤中的消解动态,并测定了土壤、小麦种子和茎杆中的最终残留.苯达嗪丙酯的最低检出限为10ng,在土壤和小麦中的最低检出浓度为0.05mg·kg-1.方法的平均添加回收率为88.7%—103.3%,变异系数为4.3%—16.4%.苯达嗪丙酯的消解动态试验表明:高剂量施药条件下苯达嗪丙酯在土壤中的半衰期分别为2.5d(北京)和3.1d(石家庄);当按推荐剂量施药时,小麦收获前10d,在土壤、小麦种子和茎杆中,北京和石家庄两地均未检出苯达嗪丙酯.

甲硫嘧磺隆在小麦及土壤中残留的分析方法

建立了一种小麦和土壤中甲硫嘧磺隆残留的检测方法,采用层析柱和SPE小柱对样品进行净化、萃取,采用C18柱,以乙腈-0.5%冰乙酸混合溶剂为流动相,于236nm检测。在选定条件下该方法的最小检出量为0.35ng,籽粒和土壤中甲硫嘧磺隆的最低检测浓度为0.018mg/kg,植株中甲硫嘧磺隆的最低检测浓度为0.050mg/kg,甲硫嘧磺隆的质量浓度在0.1～5.0mg/L之间线性关系良好。在土壤和籽粒中以0.02、0.2、2.0mg/kg进行空白样品添加试验,平均回收率为92.14%～96.41%,变异系数为3.15%～9.45%之间,在小麦植株中以0.05、0.5、2.0mg/kg进行空白样品添加试验,平均回收率为86.93%～94.80%,变异系数为6.28%～8.30%之间。该方法的灵敏度、准确度、精密度均符合农药残留技术测定要求。

麦田土壤啶虫脒的残留分析方法

确立乙腈振荡提取、弗罗里硅土SPE小柱净化麦田土壤中啶虫脒残留样本的前处理方法,建立柱程序升温、NPD检测的气相色谱残留样品检测方法。结果表明,在优化的色谱条件下,啶虫脒的色谱保留时间为9.93min,在0.5～200mg/L时,啶虫脒质量浓度与其色谱峰面积在GC-NPD上线性响应良好,回归方程为y=-3 678.37x+3 595.04(r2=0.999 8)。啶虫脒在麦田土壤0.01、0.05、0.1和1.0mg/kg的4个水平的加标回收率均大于75%,各添加水平5次平行测定值的相对标准偏差均小于5%。其准确度和精密度均符合农药残留分析的要求。该色谱条件下仪器的最低检出量为0.62ng,所建立的残留分析方法的最低检测量为0.014mg/kg,可以满足麦田土壤残留的定量检测要求。

灭草松在小麦和土壤中的残留分析方法

确立了灭草松在小麦和土壤中的残留量的气相色谱分析方法。小麦样本用甲醇提取后，用乙腈和正己烷分配。土壤样本用１０％碘甲烷、二氯甲烷提取后，萃取到二氯甲烷中柱净化后，七氟西酸酐衍生，用气相色谱电子俘获检测器检测。本方法对灭草松在小麦和土壤的平均回收率为８０％～１００％，变异系数为３．８％～１７．８％，在小麦中最低检出浓度为０．０１ｍｇ／ｋｇ，在土壤中最低检出浓度为０．００５ｍｇ／ｋｇ。

小麦植株和麦田土壤莠去津残留气相色谱分析方法研究

本研究确立了乙腈振荡提取、弗罗里硅土SPE小柱净化小麦植株和麦田土壤中莠去津残留样本的前处理方法,建立了柱程序升温、GC-NPD残留样品检测方法。结果表明,优化色谱条件下,莠去津的色谱保留时间为5.97min,在0.105～54.0mg/L浓度范围内,莠去津浓度与其色谱峰面积在GC-NPD上线性响应良好,回归方程为Y=38.79 X-120.34(R2=0.998 8)。莠去津在小麦植株和麦田土壤中0.05～1mg/kg的3个水平的加标回收率均大于75%,各添加水平3次平行测定值的RSD均小于7%。其准确度和精密度均符合农药残留分析的要求。该色谱条件下仪器的最低检出量为0.38ng,方法的最低检出浓度为0.018mg/kg(植株)和0.021mg/kg(麦田土壤),此检测灵敏度可以满足该农药在小麦植株和麦田土壤中残留的定量检测要求。

新植物生长调节剂“79401”在小麦及土壤中残留分析方法研究

小麦及土壤中的植物生长调节剂“79401”用类似层析的方式，以甲醇-氨水混合溶剂洗提．洗提液通过调节不同PH值进行液-液分配得以净化．“79401”的两个主要组分01及02分别用萤光光度法和毛细管气相色谱法测定．方法平均回收率为84．5％～98．6％．变异系数为0．86％～16．09％．本残留分析方法已应用于田间试验样品的测定．

氯氟吡氧乙酸在小麦及土壤中残留的分析方法

采用氢氧化钠-甲醇溶液提取，二氯甲烷萃取，定量甲醇、浓H2SO4条件下酯化，气相色谱法测定小麦及土壤中的氯氟吡氧乙酸，氯氟吡氧乙酸质量浓度在0．01～1．0mg·L^-1之间线性关系良好。在添加浓度0．01～0．8mg·kg^-1下，植株、土壤和籽粒中氯氟吡氧乙酸的平均回收率分别为72．3％～86．7％、83．6％～95．8％和77．7％．87．3％，变异系数分别为3．02％～8．59％、2．87％～8．46％和2．75％～7．61％。氯氟吡氧乙酸的最小检测量为1．0×10^-11g，在植株、土壤和籽粒中最低检出浓度均为0．01mg·kg^-1。该方法的准确性、精确性和灵敏度均满足农药残留分析的要求：

稻麦轮作条件下土壤硝态氮残留分析

土壤中硝态氮残留浪费了氮肥资源,加大了农业生产的资金投入,同时给地下和地表水环境带来威胁,硝态氮在土壤剖面中的含量及其空间分布特征是表征硝态氮淋失风险的重要指标。选取苏州市甪直镇淞浦村稻麦轮作土壤为试验土壤,取水稻一个生命周期为试验时间,设置氮肥施加浓度梯度,分层对土壤取样进行测定。结果表明,土壤各个耕层中硝态氮的含量在施加氮肥后都有一定程度的改变,其中不施氮肥的氮素残留减少,其他施氮肥组氮素残留均较施肥之前有所增加;土壤硝态氮主要累积在30cm和150cm以下;施氮肥量越大,土壤硝态氮在0～180cm土层范围内的累积量也越大。

啶虫脒在小麦及土壤中残留行为研究

利用气相色谱外标法定量分析检测3%啶虫脒乳油在小麦和麦田土壤中的消解动态以及残留量,为制定啶虫脒在小麦上的合理使用提供科学依据。检测结果表明,啶虫脒在小麦植株和土壤中的半衰期分别为5.3~5.8d和7.1~7.8d。啶虫脒在距离最后施药14d采样时麦秸中的残留量为0.030 5~0.182 2mg/kg,土壤中残留量为0.009 1~0.026 1 mg/kg,麦粒中残留量0.002 7~0.072 5mg/kg。