除草剂对小麦田雀麦的生物活性测定

为筛选防除雀麦Bromus japonicus的高效除草剂,采用室内生物测定法研究了13种除草剂对雀麦的除草活性及5种除草剂的田间药效试验。结果表明,在田间推荐剂量的低剂量下,氟唑磺隆、啶磺草胺、氟噻草胺、甲基二磺隆、异丙隆、磺酰磺隆、丙苯磺隆7种除草剂对雀麦具有很高的防除效果,21 d鲜重抑制率分别为88.30%、86.32%、83.97%、78.47%、76.76%、72.83%、71.39%,高剂量下的21 d鲜重抑制率达98.57%、95.36%、91.58%、91.46%、89.47%、82.48%、82.20%;其中氟唑磺隆各剂量下的防效较其它除草剂高。而嘧啶肟草醚、苯唑草酮、炔草酯、吡氟酰草胺、唑啉草酯、精噁唑禾草灵6种除草剂对雀麦防效较差。氟唑磺隆、啶磺草胺、氟噻草胺、甲基二磺隆、异丙隆5种除草剂的田间药效试验表明,氟唑磺隆对雀麦防效最高,高剂量下20 d株防效达85.04%,药后40 d株防效和鲜重防效分别达83.94%和84.17%,未见小麦有明显药害症状,建议田间推荐用量为21.00~42.00 g(a.i.)/hm~2。表明雀麦对不同除草剂的敏感性存在差异,在供试的13种除草剂中氟唑磺隆对雀麦防效最高,较为安全,为防除雀麦的理想除草剂。     

碘甲磺隆钠盐对土壤中几种生物学指标的影响

通过模拟实验研究了除草剂碘甲磺隆钠盐对土壤中脲酶、过氧化氢酶、呼吸作用及土壤微生物生物量碳的影响。结果表明:碘甲磺隆钠盐在田间施用量(1 mg/kg)下对土壤脲酶和微生物生物量碳的影响呈现为显著的抑制-恢复过程;对土壤过氧化氢酶的影响呈现出轻微的抑制-激活-恢复过程。碘甲磺隆钠盐施用初期对土壤呼吸作用也有一定的影响,浓度愈大,对土壤呼吸强度的抑制愈强,但随着时间的推移,逐步由抑制作用转为一定程度的激发作用,到12 d后施药土壤与对照组土壤的呼吸强度基本上趋于一致。统计分析结果表明,碘甲磺隆钠盐属于低毒或无实际危害的农药。     

非转基因抗除草剂玉米对三种乙酰乳酸合成酶抑制剂类除草剂的田间抗性表现

为评估中国农业大学培育的非转基因抗除草剂玉米品系958R和335R在大田条件下对乙酰乳酸合成酶（acetolactate synthase,ALS）抑制剂类除草剂的抗性表现,利用甲咪唑烟酸、砜嘧磺隆、唑嘧磺草胺3种除草剂对郑单958、958R、先玉335、335R共4种玉米杂交种进行了播后苗前土壤处理,每种除草剂设3个处理剂量（1、3、9倍推荐剂量）,并于施药2周和4周后进行株高测定,于收获晾干后测产。结果表明,在甲咪唑烟酸216、648 g（a.i.）/hm²处理下,郑单958和先玉335均已绝产,而958R和335R产量均未受影响;在砜嘧磺隆或唑嘧磺草胺高剂量处理下,常规玉米品种郑单958和先玉335株高的最高降幅分别为25.7%和35.2%,田间药害反应显著,而958R和335R则抗性反应显著。研究表明,非转基因抗除草剂玉米杂交种具有良好的田间抗性,不仅能有效解决玉米田砜嘧磺隆和唑嘧磺草胺等ALS除草剂的药害问题,还能够通过引入甲咪唑烟酸等新的ALS除草剂更好地防除玉米田的杂草。     

异噁唑草酮对玉米根际土壤微生物量碳、氮和酶活性的影响

为明确异噁唑草酮对玉米根际土壤微生物碳、氮及酶活性的影响, 采用田间试验的方法, 以1倍、5倍和10倍田间推荐剂量为供试除草剂剂量, 测定了异噁唑草酮土壤封闭处理对玉米根际土壤微生物量碳、氮及土壤脲酶、过氧化氢酶、蔗糖酶、脱氢酶和中性磷酸酶活性的影响。结果表明:推荐剂量的异噁唑草酮对玉米根际土壤微生物量碳、氮含量无显著影响, 5倍和10倍推荐剂量的异噁唑草酮对玉米根际土壤微生物量碳、氮含量具有抑制作用。推荐剂量的异噁唑草酮对玉米根际土壤脲酶、过氧化氢酶和蔗糖酶影响较小, 5倍和10倍推荐剂量的异噁唑草酮对其具有明显的抑制作用。异噁唑草酮对土壤脱氢酶活性具有抑制作用, 且施用剂量越高, 抑制作用越强。异噁唑草酮对土壤中性磷酸酶活性的影响表现为前期促进, 后期抑制, 且施用剂量越大, 促进或抑制作用越强。研究表明:推荐剂量的异噁唑草酮对玉米根际土壤微生物量碳、氮及土壤脲酶、过氧化氢酶和蔗糖酶活性的影响较小, 但对土壤脱氢酶、中性磷酸酶活性有影响。     

麦田入侵杂草小籽虉草对麦田常用除草剂的敏感性测定

为筛选能有效防除云南麦田入侵杂草小籽虉草Phalaris minor的除草剂, 采用温室盆栽法分别测定了麦田常用7种茎叶处理剂各7个梯度剂量对小籽虉草的毒力?结果表明, 在推荐剂量下, 50%异丙隆WP?5%唑啉草酯EC?15%炔草酯WP?69 g/L精噁唑禾草灵EW?7.5%啶磺草胺WG?30 g/L甲基二磺隆OD和70%氟唑磺隆WG对小籽虉草药后30 d的株防效分别为99.34%?99.43%?87.50%?75.00%?34.50%?37.50%, 54.17%, 药后30 d的鲜重防效分别为87.92%?92.66%?56.09%?74.43%?57.17%?45.61%?44.67%?所有除草剂中, 唑啉草酯的GR90接近推荐使用剂量的90%?异丙隆的GR90略高于推荐剂量, 其他除草剂的GR90远高于麦田推荐使用剂量?以上结果表明, 防治麦田杂草小籽虉草的首选除草剂为唑啉草酯, 备选除草剂种类少?     

防除宽叶酢浆草除草剂的室内生物活性评价

宽叶酢浆草Oxalis latifolia为入侵云南玉米地的进境检疫性鳞茎类杂草?为筛选防治该草的高效除草剂, 室内测定了8种除草剂对宽叶酢浆草的生物活性?结果表明, 用田间推荐剂量处理后30 d, 氯氟吡氧乙酸异辛酯(210 g/hm2)对宽叶酢浆草的鲜重抑制率超过90%, 硝磺草酮(202.50 g/hm2)?烟嘧磺隆(60 g/hm2)和砜嘧磺隆(25.13 g/hm2)处理的鲜重抑制率超过85%, 苯唑草酮(27 g/hm2)?莠去津(1 875 g/hm2)和2甲4氯钠(1 201.20 g/hm2)处理的鲜重抑制率分别为81.29%?76.36%和70.71%?1/4草甘膦推荐剂量(712.50 g/hm2)即可彻底杀死宽叶酢浆草?推荐剂量的草甘膦?氯氟吡氧乙酸异辛酯?砜嘧磺隆?烟嘧磺隆?硝磺草酮?莠去津?苯唑草酮和2甲4氯钠处理后30 d, 宽叶酢浆草的繁殖抑制率分别为100%?100%?98.17%?98.17%?90.87%?83.56%?81.74%和56.17%?其中氯氟吡氧乙酸异辛酯1/16推荐剂量(13.13 g/hm2)和草甘膦1/8推荐剂量(356.25 g/hm2)对宽叶酢浆草的繁殖抑制率仍超过90%?结果表明上述除草剂均可用于玉米地宽叶酢浆草的防除?草甘膦和氯氟吡氧乙酸异辛酯控制宽叶酢浆草生长和繁殖效果最优, 硝磺草酮?砜嘧磺隆和烟嘧磺隆也是优良的备选玉米宽叶酢浆草防治剂?     

防除稻麦连作小麦田主要杂草的高活性除草剂室内筛选

为筛选出适于防除长江中下游地区小麦田主要恶性杂草的高活性除草剂,采用室内整株生物测定法测定了日本看麦娘和猪殃殃对小麦田常用除草剂的敏感性。试验结果表明:在推荐剂量范围内,丙草胺、异丙隆、绿麦隆、氟噻草胺和吡氟酰草胺等5种小麦田除草剂土壤处理均对日本看麦娘有较好的毒力作用;精■唑禾草灵、炔草酯、唑啉草酯、甲基二磺隆、环吡氟草酮、啶磺草胺、三甲苯草酮、异丙隆、绿麦隆等9种常用除草剂茎叶处理对日本看麦娘毒力效果显著。土壤处理剂氟噻草胺、吡氟酰草胺和茎叶处理剂灭草松、氯氟吡氧乙酸、唑草酮对猪殃殃的毒力较好,ED_(90)值均低于各自推荐剂量。因此在实际生产中可以根据不同的草相应用不同的高活性除草剂,以提高防除效果。     

7种茎叶处理除草剂对野燕麦的生物活性评价

采用温室盆栽整株测定法,开展炔草酯、唑啉草酯、精噁唑禾草灵、甲基二磺隆、氟唑磺隆、啶磺草胺、异丙隆7种茎叶处理除草剂对野燕麦的除草活性评价。结果表明:15%炔草酯WP和5%唑啉草酯EC对野燕麦活性极高,ED_(90)分别为12.58和21.92 g/hm~2(有效成分,下同),约为各自推荐剂量的1/4和1/2,可作为生产中防除野燕麦的首选药剂; 69 g/L精噁唑禾草灵SC和30 g/L甲基二磺隆OD对野燕麦具有较好的防效,ED_(90)分别为47.59和14.76 g/hm~2,与各自推荐剂量相当,是生产中防除野燕麦的有效药剂; 70%氟唑磺隆WG和4%啶磺草胺OD对野燕麦活性一般,ED_(90)分别为63.03和28.36 g/hm~2,约为各自推荐剂量的2倍,可作为生产中防除野燕麦的备选药剂; 50%异丙隆WP对野燕麦活性较差,ED_(90)为7 610.39 g/hm~2,约为推荐剂量的7倍,不适合用于防除4～5叶期的野燕麦。     

啶磺草胺等8种除草剂对小麦田8种禾本科杂草的生物活性

在温室内采用盆栽整株喷雾法研究了啶磺草胺等8种除草剂对雀麦、节节麦等8种禾本科杂草的生物活性,探讨各除草剂对这些禾本科杂草的防除谱及防除效果。结果表明：啶磺草胺、氟唑磺隆和甲基二磺隆对雀麦、日本看麦娘和看麦娘的防效均较好,田间推荐剂量下（14、22.5、9 g/hm2）防效为66.74%～100%;对硬草的防效略差;对野燕麦和节节麦的防效较差;对菵草、蜡烛草略有差异,氟唑磺隆对菵草防效较好,而啶磺草胺对蜡烛草防效较好。唑啉草酯、肟草酮、炔草酯、精恶唑禾草灵和异丙隆对日本看麦娘、看麦娘、蜡烛草、硬草、菵草和野燕麦防效均较好,田间推荐剂量下防效为71.73%～100%,对节节麦、雀麦防效较差或无效。     

助剂HA对玉米田茎叶处理除草剂活性的影响

通过对玉米田茎叶处理除草剂烟嘧磺隆、硝磺草酮、唑嘧磺草胺、唑草酮和噻吩磺隆等与不同用量HA桶混使用效果的测定,初步明确了上述除草剂推荐剂量下对玉米田主要杂草的生物活性以及HA对其活性的影响,除烟嘧磺隆外,硝磺草酮、唑嘧磺草胺、唑草酮及噻吩磺隆等除草剂推荐剂量苗后单独使用对已萌发的稗草、牛筋草控制效果不理想,药后30 d生物量积累的控制效果低于70%。0.2%HA显著提高了硝磺草酮的除草活性,药后30 d对杂草生物量积累的控制效果较硝磺草酮单独使用提高10%~50%,有助于降低硝磺草酮的使用量。     

Quantitative bioassays for determining residues and availability to plants of sulphonylurea herbicides

A bioassay procedure for quantitative determination of sulphonylurea herbicides is described. Turnips (Brassica rapa) were found very suitable as test plants and gave results within 10 days. Six sulphonylurea compounds were investigated for their activity in three widely differing soils. The potential availability to plants was calculated from the dose-response curves of vermiculite (non-sorptive substrate) and the corresponding ED₅₀-values of the soils. The dose-response relationship (logistic curve) was described by a computer model by a position parameter, the slope of the curve and the minimum and maximum fresh weights of plants. The limit of quantitative detection in the range of ED₃₀ in vermiculite was 0·06 μg 1^?1 for sulfometuron and 1·03 μg 1^?1 for DPX-L5300, methy12-([4-methoxy-6-methyl-1,3,5-triazin-2-yl (methyl)carbamoyl]-sulphamoyl) benzoate. Results with turnips showed that sulfometuron was the most active compound in all substrates (ED₅₀ in vermiculite 0·12 μg 1^?1) followed by chlorsulfuron, metsulfuron-methyl, triasulfuron, DPX-M6316, methyl 3-([(4-methoxy-6-methyl-1,3,5-triazin-2-yl)aminocarbamoyl]-aminosulphaphamoyl)-2-thiophenecarboxylate, and DPX-L5300 which had ED₅₀ or 1·98 μg 1^?1, The Horotiu sandy loam soil showed the highest ED₅₀-values and the lowest plant availability for all compounds compared to the other soils. Probit and logistic evaluation methods for deriving dose-response relationships are compared and their applicability is discussed.     

包气带土壤pH对灌溉施肥响应的变异过程

为了分析灌溉施肥活动引起的包气带土壤pH值变异特征及其对地球化学条件的响应，通过历时3 a的野外原位灌溉施肥试验，应用不同季节灌前、灌后6 m土层中不同深度的测定资料，系统分析了土壤pH对灌溉、施肥的响应过程，结果表明：各深度pH值呈弱变异性（CV=1.01%~2.28%），与灌溉前相比，灌后土壤pH值的均值和变异系数均呈现明显的变化；灌前包气带各层pH具有强烈的空间自相关性，灌后受水分、基质等相互作用影响，pH的空间自相关性有所减弱，C₀/(C₀+C)和变程a分别由7.23 m和3.54 m(灌前0 d)减少到3.26 m和2.76 m(灌后第10天)。土壤基质是决定土壤酸碱性的主要因素，在灌溉施肥活动对pH的响应过程中，地球化学条件（土壤含水量、土壤温度、土壤有机质(SOM)、氧化还原电位（RP）等)、土壤基质组成和氮底物浓度（NH⁺₄-N）等的交互作用影响pH的动态。土壤含水量和温度单独对pH影响不显著，两者交互作用对pH有显著影响。引起土壤pH变化的主要变异源为Cl^-、土壤有机质(SOM)、NO^-₃-N、NH⁺₄-N等营养物质和不同空间深度土壤基质的差异，表明灌溉施肥改变了包气带pH地球化学动力场、营养物质和土壤基质的交互作用，引起各深度的生物地球化学反应，控制pH值的空间变异特性。当包气带介质土壤水分变化时，首先营养物氨态氮以分子态或水合态形式被介质吸附，H⁺得到释放，使得灌后第4天pH值下降。随着氨氧化过程中H⁺的释放，pH在灌前和灌后第10天和第30天有显著差异。氨的氧化引起硝酸盐含量不断增加，使得硝酸盐对pH值的影响在灌后不断增强,相关系数由0.24(0 d，P<0.05)增加到0.41(30 d,P<0.01)，而氨态氮对pH值的影响逐步降低，相关系数由0.43(0 d，P<0.01)降低为0.19(30 d,P>0.05)。     

Untersuchungen zum Einfluss einer Pflanzenschutzmittelspritzfolge auf das Rückstandsverhalten von Terbutryn und die mikrobielle Aktivität im Boden. Teil II. Beeinflussung der mikrobiellen Aktivität

Studies on the effect of a pesticide spray sequence on the behaviour of terbutryn residues and on soil microbial activity. Part II. Influence on microbial activity In laboratory incubation experiments (at 10 and 20°C and 30 and 60% soil water-holding capacity) soil microbial activities (dehydrogenase, respiration after glucose amendment and nitrogen transformations) were scarcely affected by 20·9 and 28·0 mg kg^?1, respectively, of terbutryn in two soils of different sorption properties. In contrast, dinosebacetate, alone or mixed with terbulryn, triadimefon or parathion, inhibited dehydrogenase activity and respiration even at a low rate of application (2·87 mg kg^?1). Following application of a 10 times higher rate to a highly adsorbent soil there was an initial inhibition of nitrification followed by an enhanced rate of nitrogen mineralization. Triadimefon and parathion, alone and in combination with other pesticides, caused both stimulation and inhibition of microbial activity; the reason is not clear. The effects on dehydrogenase and respiration were confirmed in field experiments. Dehydrogenase activity was the most sensitive and so could be a useful test for the side-effects of pesticides on soil micro-organisms. Additional work on nitrogen transformations is needed to interpret the results.     

高效液相色谱法测定小麦和土壤中炔草酯及其代谢物炔草酸的残留量

建立了应用高效液相色谱分别测定炔草酯及其代谢物炔草酸在小麦和土壤中残留量的方法。样品经乙酸乙酯或丙酮提取,中性氧化铝柱层析净化,高效液相色谱法测定。结果表明:炔草酯在小麦籽粒、植株和土壤中的平均回收率为80.4%~92.5%,相对标准偏差(RSD)为1.5%~4.4%;炔草酸的平均回收率为71.7%~83.8%,RSD为2.3%~6.0%;炔草酯和炔草酸的最小检出量分别为1.0×10-9和2.0×10-10 g;在籽粒、植株和土壤中炔草酯和炔草酸的最低检测浓度分别为0.02、0.05、0.02 mg/kg和0.01、0.02、0.01 mg/kg。     

Influence of nitrogen fertilisers on the persistence of carbaryl and carbofuran in flooded soils

Ammonium sulphate and urea, but not potassium sulphate, increased the persistence of carbaryl in a flooded laterite soil with a low native nitrogen content (0.04%), but not in an alluvial soil with a higher nitrogen content (0.11%). Thus, NH₄⁺ but not SO₄^2-, contributed to the increased persistence of carbaryl. Likewise, ammonium sulphate increased the persistence of carbofuran in the laterite soil, but not in the alluvial soil. Significant accumulations of 1-naphthol and 2,3-dihydro-2, 2-dimethylbenzofuran-7-ol (‘carbofuran phenol’), in soils treated with carbaryl or carbofuran, suggested hydrolysis as the major pathway of degradation. Treatment of the two soils with ammonium sulphate, urea or potassium sulphate led to a decrease in soil-bound residues and an increase in the respective hydrolysis products, compared with untreated soils. Sorption studies indicated that NH₄⁺ and SO₄^2- compete with carbaryl, 1-naphthol and carbofuran for sorption and exchange sites in the complex soil system. Evolution of [¹⁴C]carbon dioxide from ring-¹⁴C in carbaryl and carbofuran was negligible. Consequently, after 40 days, more than 50% of the ¹⁴C in [¹⁴C]carbaryl and [¹⁴C]carbofuran remained in the soils as hydrolysis products (1-naphthol or 2,3-dihydro-2,2-dimethylbenzofuran-7-ol) plus soil-bound residues.     

Degradation and adsorption of carbendazim and 2-aminobenzimidazole in soil

Increasing adsorption of [¹⁴C]-labelled carbendazim in soil took place within a few weeks of incubation and was greatest in soil with a high organic matter content. Carbendazim was slowly decomposed in soil, mainly by soil microorganisms. After 250 days of incubation in two unsterilised soils, 13 and 5% respectively of added [¹⁴C]-carbendazim was recovered compared with 70 and 50% respectively from sterile soils; 4–8% of added carbendazim was recovered as 2-aminobenzimidazole (2-AB) from both unsterilised and sterile soil. After 270 days' incubation, 33 and 9% of ¹⁴C was recovered as ¹⁴CO₂ from soil supplied with [¹⁴C]-carbendazim (20 and 100 mg/kg) respectively. Degradation started more rapidly when carbendazim was added to soil preincubated with the fungicide but the degradation rate was very low in all cases, indicating that the compound is a poor microbial energy source and that the degradation is a co-metabolic process. 2-AB was found as a degradation product although it appeared to be unstable in soil, decomposing rapidly after a lag period of about 3 weeks; small amounts remained in the soil for several months, however, presumably adsorbed on soil particles.     

Inhibitory Effects of Fungicides on Hydrolysis of Urea and Nitrification of Urea Nitrogen in Soil

The influence of 1 and 50 mg active ingredient (AI) kg^-1 soil of 17 fungicides on transformations of urea nitrogen in soil was studied by determining the amounts of urea hydrolysed and the amounts of nitrate and nitrite produced when samples of two coarse-textured and two fine-textured soils were incubated aerobically for various times after treatment with urea. When applied at the rate of 1 mg AI kg^-1 soil, anilazine, benomyl, captan, chloranil, mancozeb and thiram retarded urea hydrolysis in the two coarse-textured soils and maneb retarded urea hydrolysis in all four of the soils used. Most of the fungicides tested retarded nitrification of urea nitrogen in the two coarse-textured soils when applied at the rate of 1 mg AI kg^-1 soil, but only etridiazole markedly retarded nitrification of urea nitrogen in all of the soils used when applied at this rate. When the fungicides were applied at the rate of 50 mg AI kg^-1 soil, anilazine, captan, chloranil, fenaminosulf, folpet, maneb, mancozeb and thiram retarded urea hydrolysis in the four soils studied, and all fungicides tested except chloroneb, fenarimol and iprodione retarded nitrification of urea nitrogen in these soils. One-way analysis of variance and correlation analyses indicated that the inhibitory effects of the 17 fungicides tested on nitrification of urea nitrogen in soil increased with decrease in the organic-matter content and increase in the sand content of the soil. © of SCI.     

磺草酮在土壤中的淋溶特性研究

基于所建立的土壤中磺草酮残留的超高效液相色谱-串联质谱分析方法,通过土壤薄层层析试验研究了磺草酮在中国3种典型土壤中的淋溶特性。结果表明:添加水平为1和10 mg/kg时,磺草酮在土壤中的添加回收率为80%~104%,相对标准偏差为1.2%~8.1%,最低检测浓度为0.1 mg/kg。磺草酮在河北潮土、湖南红土和吉林黑土中的比移值(Rf)分别为0.563、0.101和0.422,其在潮土和黑土中的移动性为中等,在红土中为不易移动;磺草酮在土壤中的淋溶特性与土壤理化性质密切相关,主要影响因素是土壤p H值及黏粒组分含量。     

盐碱地不同施氮量对土壤微生物区系与食葵产量的影响

在内蒙古河套灌区盐碱食葵田进行大田试验,以不施氮肥为对照(CK),设置了75 kg·hm~(-2)(N1)、150kg·hm~(-2)(N2)、225 kg·hm~(-2)(N3)、300 kg·hm~(-2)(N4)、375 kg·hm~(-2)(N5)五个氮肥施用水平,研究了不同氮肥施用量对土壤微生物区系和食葵产量的影响。结果表明:(1)盐碱地施用氮肥可提高土壤微生物数量和细菌优势菌菌群多样性,各处理0~20 cm土层根区土壤微生物数量大小顺序为N4N3N5N2N1CK,各施肥处理较CK差异极显著(P0.01);(2)盐碱地施用氮肥可促进食葵生长发育,提高产量,随氮肥施用量由低到高,食葵长势和干物质积累呈逐渐增加趋势,产量与施氮量呈抛物线型关系,各处理产量分别较CK提高0.06%、36.27%、61.95%、105.36%和85.03%;(3)适量施氮可抑制土壤积盐,食葵收获后,各处理积盐量大小顺序为N2CKN5N3N1N4;(4)土壤微生物的数量和优势菌菌群数与氮肥施用量、食葵根干重呈正相关关系,与土壤含盐量和积盐量呈负相关关系。综合试验结果,内蒙古河套灌区中度盐碱地食葵生产中氮肥适宜施用量为300 kg·hm~(-2)。     

0.2%苄嘧磺隆·丙草胺颗粒剂在水稻田中的残留及消解动态

采用高效液相色谱（HPLC）法研究了0.2%苄嘧磺隆·丙草胺颗粒剂在稻田环境中的消解动态和最终残留。稻田水、谷壳、稻秆和水稻植株样品用二氯甲烷提取,土壤样品用V（二氯甲烷）:V（甲醇）=9:1的混合液提取,糙米样品用V（二氯甲烷）:V（甲醇）=7:3的混合液提取后再用二氯甲烷萃取;HPLC法测定。结果表明:当添加水平在0.05~1 mg/kg（或mg/L）时,苄嘧磺隆和丙草胺的平均回收率均在75%~103%之间,相对标准偏差（RSD）为1.6%~13%;苄嘧磺隆和丙草胺的检出限（LOD）均为0.02 mg/L,最小检出量均为4.0×10-10 g,在稻田水中的最低检测浓度（LOQ）均为0.001 mg/L,在稻田土壤中的LOQ均为0.005 mg/kg,在水稻植株、谷壳和糙米中的LOQ均为0.01 mg/kg。在水稻移栽后5~7 d,采用直接撒施法在高剂量（270 kg/hm2,其中苄嘧磺隆有效成分为67.5 g/hm2,丙草胺有效成分为472.5 g/hm2）下施药1次的消解动态试验结果表明:在稻田水、土壤和水稻植株中,苄嘧磺隆的消解半衰期分别为5.06~5.83 d、9.76~11.55 d和4.52~4.82 d,丙草胺的消解半衰期分别为5.94~6.45 d、7.70~9.90 d和4.11~4.89 d。分别按低剂量（180 kg/hm2,其中苄嘧磺隆有效成分为45 g/hm2,丙草胺有效成分为315 g/hm2）和高剂量（270 kg/hm2）施药1次,在正常收获期收获的糙米中均未检出苄嘧磺隆和丙草胺残留。