噁草酮防除直播稻田杂草稻的施用技术

为确立噁草酮防除直播稻田杂草稻的施用技术,通过温室盆栽试验比较了噁草酮在不同土壤水分环境下对栽培稻的安全性及对杂草稻的防效,并在大田中比较了不同直播方式下其对杂草稻的防效及栽培稻产量的影响。结果表明,透气条件下,噁草酮对栽培稻的药害最低,但对杂草稻的防效也较差;饱和水分条件下对杂草稻防效较好,150 g(a.i.)/hm~2时其出苗率和鲜重的抑制率达89.61%和61.87%,超过450 g(a.i.)/hm~2时完全抑制出苗;但药后播种对栽培稻安全性较高,600 g(a.i.)/hm~2下对其出苗率和鲜重的抑制率仅分别为38.06%和39.96%,播后施药的药害较重,最低剂量150 g(a.i.)/hm~2时抑制率已分别达88.77%和45.52%;淹水条件下,虽对杂草稻有100%的防效,但也完全抑制栽培稻出苗。大田施用噁草酮300、450、600 g(a.i.)/hm~2,旱直播和水直播方式下杂草稻株防效分别为26.88%、43.54%、44.45%和84.88%、85.74%、90.92%;鲜重防效分别为11.58%、20.16%、27.33%和30.86%、53.68%、80.15%。旱直播和水直播方式下施用量分别超过450、300 g/hm~2时栽培稻产量显著增加。综合分析,推荐水直播整地后泥水状态施用300 g(a.i.)/hm~2噁草酮,水层落干后播种,保持土壤湿润且土表不出现水渍,栽培稻顺利出苗后及时上水且不淹没苗心为宜。     

几种封闭除草剂两个时期用药效果对比及其交互作用分析

通过田间小区试验评价了前期筛选的几种适用“播喷同步”的封闭除草剂对水稻的安全性及对直播田杂草的防效, 明确了“播喷同步”技术与常规播后4 d封闭的差异, 以及施药时期×除草剂种类交互作用及对控草效果的影响, 优化水稻直播田杂草防控策略?试验结果表明, 播种当天(播喷同步)或播种后4 d(常规方法)喷施120 g/L噁草酮EC 360 g/hm2+10%苄嘧磺隆WP 30 g/hm2(有效剂量, 下同)?33%嗪吡嘧磺隆WG 74.25 g/hm2+300 g/L丙草胺EC 450 g/hm2?60%丁草胺EC 1 350 g/hm2+10%吡嘧磺隆WP 30 g/hm2?35%吡嘧·嘧草·丙OD 525 g/hm2?300 g/L丙草胺EC 450 g/hm2+10%苄嘧磺隆WP 30 g/hm2, 5组除草剂处理对直播稻均无可见药害, 各“播喷同步”处理的杂草防除效果不低于常规播后4 d用药; 同步喷施33%嗪吡嘧磺隆WG+300 g/L丙草胺EC防效最高, 药后35 d对禾本科?莎草科?阔叶草防效达到98.3%及以上; 水稻直播4 d后喷药, 水稻成苗率提高但 35 d 的禾本科杂草防效低, 33%嗪吡嘧磺隆WG+300 g/L丙草胺EC处理受喷药时间影响小; 复合双因子方差分析表明, 单一因子会对水稻安全性?杂草防效产生显著影响, 用药时期×除草剂种类交互对水稻安全性无显著影响, 对控草效果影响显著?因此, 直播田封闭除草剂宜尽早施药提高防治效果, 同时应选用安全高效的除草剂, 33%嗪吡嘧磺隆WG+300 g/L丙草胺EC处理, 可于播种当天到播种后4 d内用药, 保障直播田杂草防治效果的同时兼顾水稻安全?     

25％双环磺草酮悬浮剂防除杂草稻的使用策略

杂草稻Oryza sativa f. spontanea是一种危害水稻生产、具有杂草特征的水稻，筛选可防除杂草稻的除草剂可有效解决防除杂草稻的难题。为明确25%双环磺草酮悬浮剂(SC)防除杂草稻的使用策略，采用盆栽试验测定了25%双环磺草酮SC 不同用药剂量、用药时间和用药方式 (喷雾法和毒土法) 对杂草稻的防除效果及对水稻的安全性。结果表明:25%双环磺草酮SC按有效成分150~375 g/hm2的剂量分别于杂草稻萌芽期、立针期、1~2叶期和2~3叶期施用，当采用喷雾法施药时，其对杂草稻的株数防效分别达98.0%~100%、94.0%~100%、94.0%~100%和83.0%~100%，而采用毒土法施药时，其防效分别为51.0%~100%、56.0%~93.0%、27.0%~89.0%和28.0%~71.0%；在有效成分为187.5 g/hm2和375 g/hm2剂量下，喷雾法施药对水稻各项生长指标无不良影响，而毒土法施药则对水稻株高、根长、根系和植株鲜重等均有抑制作用。表明与毒土法相比，喷雾法施药具有防除效果好、使用期宽和对水稻安全性高等优点，但该药的速效性较差，施药后20~30 d方能达到最佳防效。本着高效、经济、安全的原则，推荐25%双环磺草酮SC防除杂草稻的使用策略为:于杂草稻萌芽期至1~2叶期采用喷雾法施药，推荐使用剂量为有效成分150~187.5 g/hm2，如推迟至杂草稻2~3叶期防除，则使用剂量应提高至187.5~225 g/hm2。施药时应有水层1~2 cm，施药后保持水层5 d以上。     

胺苯·丙酯草醚油菜田应用技术研究

胺苯.丙酯草醚杀草谱较广,对移栽油菜田中禾本科杂草和阔叶杂草具有较好的防效,药效优于各单剂丙酯草醚和胺苯磺隆,与草除.精喹EC相当;在46.5~55.8 g a.i./hm2剂量下能有效防除禾本科杂草看麦娘、日本看麦娘,及阔叶杂草繁缕、牛繁缕、碎米荠、猪殃殃、野老鹳草,防效达到80%~90%,对稻槎菜防效一般(50%左右),对巢菜、草、棒头草和早熟禾基本无效;速效性一般,持效期在90 d以上;最佳施药时期为杂草1~3叶期的苗后早期;推荐使用剂量为46.5~55.8 g a.i./hm2,剂量在93 g a.i./hm2内对油菜安全。     

丙草胺对干籽直播稻安全性的研究

水稻干籽播种,播后2~4 d施30%丙草胺EC 2 250 mL/hm2或30%丙草胺EC 2 250 mL/hm2+10%苄嘧磺隆WP 300 g/hm2,稻田进行湿润管理,对水稻出苗及生长安全。使用丙草胺后淹水,水稻出苗率下降,齐苗期、第一叶抽出期推迟,叶片、叶鞘缩短,稻苗矮小,其药害程度随淹水时间的延长、用药量的增加而加重。干籽直播稻田使用丙草胺必须严格把握两点:一是掌握在播种上水后2~4 d用药;二是三沟配套,排灌通畅,施药后至齐苗前田间无积水,确保幼根先于幼芽长出。     

稻鳝种养田杂草群落组成及不同除草剂对黄鳝生长的影响

为了明确稻鳝种养田杂草群落组成及除草剂安全用药技术,采用取样计数的方法调查了稻鳝种养田杂草种类及田间密度,并采用静水式试验法在室内条件下测定了稻田常用除草剂对黄鳝生长的影响。结果表明,稻鳝种养降低了杂草的丰富度、多样性和均匀度,杂草危害减轻。茎叶处理除草剂100 g/L氰氟草酯EC、25 g/L五氟磺草胺OD、13%2甲4氯钠AS和480 g/L灭草松AS对黄鳝生长安全,可安全应用于稻鳝种养田防除杂草。土壤处理除草剂中,30%丙草胺EC、10%吡嘧磺隆WP、40%苄嘧磺隆·丙草胺WP对黄鳝生长安全,是稻鳝种养田使用土壤处理除草剂的优先选择。60%丁草胺EC和12%噁草酮EC与黄鳝的死亡率存在着明显的剂量-效应关系,随着浓度的提高,黄鳝死亡率显著上升,不推荐用于稻鳝种养田防除杂草。     

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。     

不同时期施用7.5%啶磺草胺WG防除麦田杂草的效果

啶磺草胺无论冬施或是春施,对耐药性较强的禾本科杂草早熟禾防效显著。用7.5%啶磺草胺WG270～375 g/hm2株防效可达90%以上。     

机插秧同步施用噁草酮-复合肥缓释颗粒剂的研制及其田间应用

稻田草害是影响中国机插秧生产最严重的限制因素之一,研发机插秧时可同步施用的除草剂产品和杂草防控技术是移栽稻亟需解决的问题。本文以噁草酮和复合肥为核心,采用聚乳酸进行包膜,制得3种具有不同缓释时间的噁草酮-复合肥缓释颗粒剂 (噁草酮有效成分含量0.25%);在田间小区试验条件下,比较了该缓释颗粒剂在机插秧时同步施药对秧苗的安全性 及对杂草的封闭防除效果。结果显示:具有不同缓释时间的噁草酮-复合肥缓释颗粒剂按 180 kg/hm2(含噁草酮有效成分450 g/hm2) 于机插秧当天施用到田间,3~7 d后崩解释放,插秧后35 d时秧苗株高、地上部分鲜重及分蘖数显著高于对照药剂噁草酮乳油和吡嘧磺隆 ? 西草净 ? 扑草净可湿性粉剂在机插秧5 d后拌肥毒土法施用。噁草酮-复合肥缓释颗粒剂180 kg/hm2剂量下对田间主要杂草稗草、鸭舌草等的防效达90%以上,与两种对照药剂封闭处理杂草的防效相当。当噁草酮-复合肥缓释颗粒剂降低至80%用量 (144 kg/hm2) 时,对机插秧苗的安全性及田间杂草的防效与推荐剂量下的无显著差异。所有试验处理对机插秧苗无明显药害产生。此外,本研究还对噁草酮-复合肥缓释颗粒剂大面积机械化的应用技术进行了探索,采用改良的侧深施肥插秧机按180 kg/hm2的施药剂量在插秧的同时将该药肥颗粒均匀撒施在土壤表面,可实现机插秧同步精准机械用药,满足机插秧生产日益增长的省时省工需求。     

五氟磺草胺·氰氟草酯OF对水直播稻田杂草的防除效果

6%五氟磺草胺·氰氟草酯OF是陶氏益农公司开发的直播田新型除草剂.田间试验结果表明,五氟磺草胺·氰氟草酯OF对水稻田中禾本科杂草、阔叶草及莎草科杂草的防效良好.在60.0～180.0 g(ai)/hm2量范围内对水稻安全,不影响水稻的生长和发育.其适宜的施用剂量为90.0～120.0 g(ai)/hm2,施药适期为水稻3～5叶期,稗革3～4叶期,千金子2～3叶期.     

Chemical control of weedy rice in precise hill‐direct‐seeded rice in South China

Precise hill‐direct‐seeded rice, which is both cost‐ and labor‐saving, is based on the direct seeding of rice by using a precision rice hill‐drop drilling machine. Weedy rice (Oryza sativa f. spontanea), also known as “red rice”, is a major weed in precise hill‐direct‐seeded rice, causing an ≤80% yield loss and a reduction in grain quality. The aim of this study was to evaluate the control efficiency of weedy rice by pretilachlor (a pre‐emergence herbicide) and fenclorim (a safener) and their safety for precise hill‐direct‐seeded rice in two consecutive years. The amount of rice seed germination was accelerated by soaking the seeds in the safener at 0.67 g ai L^?1 for 1 h before sowing. The pre‐emergence pretilachlor treatments were applied 2 days after sowing cultured rice. The inhibition of the shoot fresh weight of the cultured rice was reduced by 3.3, 6.4 and 7.4% with 450, 900 and 1350 g ai ha^?1 of pretilachlor at 32 days after sowing (DAS) and that of the root fresh weight was reduced by 2.6, 4.9 and 8.1%, respectively. With fenclorim and pretilachlor in a precise hill‐direct‐seeded rice field in 2010 and 2011, the weedy rice control efficiency at 32 DAS was reduced by 100 and 98.0%, respectively. The pre‐emergence pretilachlor treatments that were applied at 2 DAS were much more efficient in the weedy rice control and less inhibitory to the cultured rice growth. The rice yield was increased by 26.1–26.7% in the mechanical precise hill‐direct‐seeded rice, relative to the manual‐seeding rice, with the application of fenclorim and pretilachlor.     

Differential glutathione S-transferase isozyme activities in rice and early watergrass seedlings

Glutathione S -transferase (GST) isozymes were investigated in one-leaf-stage rice ( Oryza sativa L. cv. Nipponbare) and early watergrass ( Echinochloa oryzicola Vasing) shoots after being induced by treatment with a combination of pretilachlor [2-chloro-2',6'-diethyl-N-(2-propoxyethyl)acetanilide] and fenclorim (4,6-dichloro-2-phenylpyrimidine) using DEAE-Sephacel anion exchange chromatography. Non-treated plants contained GST isozymes that had activity to the following substrates: three isozymes for l-chloro-2,4-dinitrobenzene (CDNB), six isozymes for pretilachlor and three isozymes for fenclorim in rice shoots; and four isozymes for CDNB, three or four isozymes for pretilachlor and two or three isozymes for fenclorim in early watergrass shoots. Glutathione S -transferase isozyme activities of non-treated plants were higher in rice than in early watergrass, especially in the case of GST activity with fenclorim as a substrate. Pretreatment of rice roots with a combination of pretilachlor and fenclorim increased the activity of the constitutively expressed isozymes that exhibited activity with CDNB, pretilachlor and fenclorim. This pretreatment also caused the appearance of one new GST(fenclorim) isozyme. Pretreatment of early watergrass roots with a combination of pretilachlor and fenclorim produced almost no increase in activity of some constitutively expressed isozymes that exhibited activity to CDNB and fenclorim, although it partly increased the peaks to corresponding to pretilachlor. The induction of GST was higher in rice than that in early watergrass. These results indicated that the isozyme pattern and substrate specificity of GST isozymes in rice were different from those in early watergrass. Furthermore, the selectivity of pretilachlor between rice and early watergrass may be related to different constitutively expressed GST(pretilachlor) isozyme activities and the induction of GST(pretilachlor) isozyme activities in the combination treatment.     

新型酰胺类除草剂NC1的除草作用及对水稻的安全性

为了明确新型除草剂NC1的杀草谱、施药时期、使用剂量及对水稻的安全性,采用种子生物测定法测定34.5％ NCI悬浮剂对稗草的生物活性,并与30乡丙草胺乳油进行比较;采用室内整株生物测定法测定34.5％NC1 SC不同时期处理对禾本科杂草的控制作用和对水稻的安全性,并进行田间验证.结果 表明:NC1对稗草种子的生物活性优...     

Relationship between safening activity of dymron and fenclorim to pretilachlor and glutathione S-transferase activity in rice

Dymron [1‐(α,α‐dimethybenzyl)‐3‐(p‐tolyl)urea] and fenclorim (4,6‐dichloro‐2‐phenylpyrimidine) were found to exhibit a safening activity on the growth of rice (Oryza sativa L.) seedlings against pretilachlor [2‐chloro‐2′,6′diethyl‐N‐(2‐propoxyethyl)acetanilide] injury. By pretilachlor treatment at 10^–6 and 10^–5 mol L^–1, the elongation of the third leaves of rice seedlings was reduced by approximately 20 and 40%, and that of the fourth leaves was reduced by approximately 40 and 80%, respectively. Upon the treatment of dymron at 3 × 10^–6 and 10^–5 mol L^–1 in combination with pretilachlor, the growth inhibition was half alleviated in the third leaves, and the length of the fourth leaves was almost recovered from 10^–6 mol L^‐1 pretilachlor injury, and was 20–25% recovered from 10^–5 mol L^–1 pretilachlor injury. Upon the treatment of fenclorim at 3 × 10^–6 and 10^–5 mol L^–1 in combination with pretilachlor, the growth inhibition of rice seedlings was almost alleviated in both the third and the fourth leaves. This result indicated that dymron and fenclorim showed almost the same safening effect on the fourth leaf growth against 10^–6 mol L^‐1 pretilachlor injury, although fenclorim showed higher effects at higher concentrations of pretilachlor. Glutathione S‐transferase (GST) activities in rice seedlings were investigated after being treated with a herbicide and safener. By pretilachlor treatment at 10^–6 and 10^–5 mol L^–1, the GST activity was approximately 32 and 72% increased in roots, respectively, and a little increased (7–13%) in shoots of two‐leaf‐stage rice seedlings. By dymron treatment at 3 × 10^–6?10^–5 mol L^–1, the GST activity was 2–30% increased in roots, but was not increased in shoots. By their combination treatment, the GST activity was almost the same or less than that by treatment with pretilachlor alone. In contrast, by fenclorim treatment alone, the GST activity was 43–52 and 33–45% increased in roots and shoots of rice seedlings, respectively. By the combination treatment of pretilachlor and fenclorim, the GST activity was increased 73–126% in shoots and 101–139% in roots, and was much more increased in both shoots and roots compared with treatment of pretilachlor or fenclorim alone. It was found that dymron showed less effect in increasing the GST activity than fenclorim. It is also suggested that dymron did not increase the GST activity in shoots but did increase it slightly in roots, and showed almost no effect on GST increase by pretilachlor in shoots, or rather reduced the increase in roots. From the above results, fenclorim and dymron may have different mechanisms of safening effects on the protection of rice seedlings against pretilachlor injury.     

Differential safening activity of dymron and fenclorim on pretilachlor injury in rice seedlings in soil

The safening activity of dymron [1-(α,α-dimethylbenzyl)-3-( p -tolyl)urea] and fenclorim [4,6-dichloro-2-phenylpyrimidine] on the phytotoxic activity of pretilachlor [2-chloro-2',6'-diethyl- N- (2-propoxyethyl)acetanilide] on rice seedlings was examined in both water and soil culture. The safening activity of fenclorim in water culture was greater than that of dymron, whereas the activity of fenclorim in soil was lower than that of dymron. The fenclorim concentration in soil water was lower than that of dymron at all times when determined after the application at the same concentrations. The phytotoxic activity of pretilachlor and the safening activities of dymron and fenclorim were well correlated with the concentration of each in soil water but not with the amount in total soil. The adsorption of fenclorim on soil solids was greater than those of dymron and pretilachlor. It was suggested that both the phytotoxic activity of pretilachlor and the safening activities of dymron and fenclorim were dependent on their concentrations in soil water, which were primarily dominated by the adsorption on soil.     

双唑草腈的除草活性及对不同水稻品种和后茬作物的安全性

双唑草腈(pyraclonil)为原卟啉原氧化酶(PPO)抑制剂,为明确其在水稻田的应用前景,采用室内生物测定法研究了双唑草腈的除草活性及对不同水稻品种的安全性,通过大田试验作了进一步验证,并评价了双唑草腈对水稻及后茬作物的安全性。结果表明,双唑草腈对水稻田禾本科杂草稗草、阔叶杂草鸭舌草均有很好的除草活性。在室内试验中,该药剂对稻田稗草和鸭舌草的ED50分别为11.50g/hm~2和8.22g/hm~2,均高于对照药剂丙草胺对稗草和鸭舌草的活性;双唑草腈在3种水稻和稗草之间的选择性指数分别为4.15、3.44和3.73,高于对照药剂;田间试验结果显示,1.8%双唑草腈颗粒剂162、216、324g/hm~2处理在药后20、40d对稗草、鸭舌草、节节菜及异型莎草的株防效均在98%以上,显著优于对照药剂80%丙炔噁草酮可湿性粉剂和50%丙草胺乳油;双唑草腈对水稻以及三种主要后茬作物小麦、油菜和小白菜安全。研究表明双唑草腈具有很好的应用前景。     

广东省杂草稻防控技术初探

研究了不同防控技术对杂草稻的防控效果,结果表明：30％丙草胺乳油处理杂草稻株防效为14.27％～41.04％,1次50％瑞飞特乳油处理防效74.09％～91.15％;鲜重防效以2次处理最高;各处理水稻结实率增加9.53％ ～11.55％,实际产量增加28.9％～68.8％.其中,以水稻浸种剂浸种＋2次50％瑞飞特乳油处理的杂草稻防除效果最佳,水稻增产最显著.     

栽培措施对杂草稻和栽培稻生长的影响

无论何种杂草稻密度和移栽措施下,杂草稻生长受到明显抑制,栽培稻生长没有受到明显影响,移栽不仅较好地抑制了杂草稻的发生,同时保证水稻产量,使产量达到3 496.65 kg/hm2。旱直播对杂草稻出苗率影响较小,造成杂草稻密度过高,栽培稻产量严重降低,较移栽下降了1 011.15 kg/hm2。水直播对杂草稻出苗抑制作用要明显优于旱直播,使得杂草稻出苗率较旱直播下降9.14%,但是水直播对杂草稻出苗后的生长抑制不明显,使得杂草稻发生量达到1 219.35 kg/hm2,栽培稻产量仅为1 829.85 kg/hm2。随着杂草稻密度的增大,对自身种群的影响主要表现为个体地上部分干生物量显著降低和抽穗时间的推迟;其对栽培稻的影响主要表现在栽培稻剑叶宽、分蘖数、有效穗数、地上部分干生物量、穗长、每穗饱粒数、每穗总粒数、千粒重和实际产量等方面随着杂草稻密度的增加而逐渐降低。综合考虑各方面因素,可以在杂草稻发生较为严重的田块使用移栽措施,在杂草稻发生中等的田块使用水直播措施,并且适当提高栽培稻播种量。在杂草稻发生较少的田块使用旱直播措施,从而达到成本和收益的平衡。     

双唑草腈对双季水稻田杂草的防效及后茬作物的影响

通过大田试验测定了双唑草腈及其与苄嘧磺隆、五氟磺草胺和扑草净混用对双季水稻田杂草的防效,并评价了双唑草腈对水稻及后茬作物的安全性。结果表明:2%双唑草腈GR对双季水稻田杂草具有良好的防治效果,210、315和420 g/hm~2处理药后30、45 d对禾本科杂草和阔叶类杂草的防效均在87%以上,低剂量140 g/hm~2处理药后30、45 d对双季水稻田禾本科杂草和阔叶类杂草防效均在75%以上。2%双唑草腈GR 140、210、315和420 g/hm~2处理对后茬作物小白菜、马铃薯、小麦、紫云英和冬季油菜生长安全。2%双唑草腈GR以140、210 g/hm~2分别与苄嘧磺隆或五氟磺草胺混用,药后30、45 d对禾本科杂草和阔叶杂草的防效均在93%以上,显著优于2%双唑草腈GR相应浓度的单剂处理,其中2%双唑草腈GR 210 g/hm~2+10%苄嘧磺隆WP 30 g/hm~2混用可以达到2%双唑草腈GR 315 g/hm~2处理的防治效果,且对水稻生长安全;单独施用50%扑草净WP 450 g/hm~2对双季稻田禾本科杂草的防效较差,其与2%双唑草腈GR混用后防效显著提高,但对水稻生长有较强的抑制作用。综上,双唑草腈及其与苄嘧磺隆、五氟磺草胺混用对双季水稻安全,可在双季水稻田推广应用。