The effect of systemic fungicides,applied as seed treatments or early foliar sprays,on speckled leaf blotch of wheat, Mycosphaerella graminicola (Fuckel) Schroeter

Control of speckled leaf blotch (Mycosphaerella graminicola) of wheat (Triticum aestivum) with systemic fungicides used as seed treatments or foliar sprays was studied. Seed treatment with either imazalil (1·125 g/kg seed), nuarimol (0·2 g/kg), thiabendazole (1·5 and 0·75 g/kg), triadimenol (0·3 and 0·2 g/kg) or Shell WL 47675 (0·415 g/kg) reduced the number of infected plants by 28–62% when assessments were made 11 weeks after sowing. Thiabendazole (1·5 and 0·75 g/kg) and triadimefon (0·3 and 0·2 g/kg) slowed the development of speckled leaf blotch for c. 15 weeks after sowing. A single foliar spray of triadimefon (125 g/ha) slowed the development of the disease for c. 10 weeks, but a single spray of benomyl controlled it for the whole season. There was no additional benefit from combining a seed treatment of triadimefon (0·225 g/kg) with the foliar spray.     

Factors influencing the effects of fungicide treatment on seedling emergence of perennial ryegrass (Lolium perenne)

Seeds of perennial ryegrass were sown by hand in micro-plots. Six treatment factors were applied, in all combinations, totalling thirty-two treatments. The factors were (a) firm vs light compaction of the seedbed, (b) 1 cm vs 2·5 cm sowing depth, (c) fertilizer applied to seedbed vs no fertilizer, (d) fungicides applied to the seed and seedbed vs no fungicide, (e) pesticide applied to seedbed vs no pesticide, and (f) soil kept moist after sowing vs soil kept dry after sowing. Overall, seedling emergence was increased by moist soil (18%), fungicides (16%) and by sowing at 1 cm depth (8%). In dry soil, fungicides increased emergence by 32% but had no effect in moist soil.
In other experiments, micro-plots were sown at monthly intervals, from April to October. Seeds were either treated with benomyl + captan (3 g + 3 g a.i. (kg seed)⁻¹) or not treated, and the plots were either covered to keep the soil dry, or uncovered. Seedling emergence on uncovered plots was increased significantly, by 16–28%, at the May, June, July and August sowings, when soil temperatures were at their highest and soil moisture contents at their lowest. On covered plots fungicides significantly increased emergence at the June sowing only, by 16%. The reasons for this anomaly are discussed.     

Model of stripe rust infection and control on irrigated wheat in the murrumbidgee irrigation areas of new South Wales

A well-developed epidemic of stripe rust on a field crop of a susceptible wheat cultivar (cv. Avocet) led to significant yield reductions compared to plots which were protected with regular applications of the fungicide triadimefon (Bayleton®). A modified logistic transformation of the leaf infection data provided values of apparent infection rate, r, which are required for use in simulation models of disease progress and predicted yield loss, such as epidemic and epipre. Flagleaf area at early water stage of the kernels (86 days following sowing, DFS; Zadoks growth stage 70), afforded a good prediction of grain yield. Stripe rust infection of the flag leaf had a strong negative effect on final grain yields larger than would have been predicted solely from a loss of photosynthetic area. Flood irrigation did not affect the level of disease on the flag leaf at 86 DFS nor the apparent infection rate of stripe rust on the flag leaf. Irrigation gave increased grain yield only in sprayed treatments. Conversely, while there was a yield response due to fungicide application to cv. Avocet in both irrigated and non-irrigated plots, the cost benefit of spraying the latter was marginal.     

Insecticidal control and economic damage of sugar-cane wireworm, Agrypnus variabilis (Candèze) in maize

Six insecticides (terbufos, chlorpyrifos, ethoprophos, phoxim, bendiocarb and lindane) were tested against sugar-cane wireworm Agrypnus variabilis (Candèze) in maize. The first five insecticides were applied at 0·25, 0·5 and 0·75 kg a.i./ha (2·27, 4·55 and 6·82 g a.i./100 metres of row) while lindane was applied at the registered rate of 0·29 kg a.i./ha (2·64 g a.i./100 metres of row). In addition, bendiocarb was applied as a seed treatment at the rates of 4000 and 6000 ppm. The insecticides were applied at planting as insecticide/fertilizer mixtures in 18 cm wide bands, 2–3 cm below the soil surface and 3–5 cm above the seed. The minimum effective rates were terbufos 0·25 kg a.i./ha, lindane 0·25 kg a.i./ha and chlorpyrifos and ethoprophos both at 0·5 kg a.i./ha. These treatments gave at least 5 weeks' residual control. The bendiocarb seed treatments were phytotoxic. No residues were detected in the cobs or grain at the minimum effective rates of the terbufos, chlorpyrifos or ethoprophos treatments. The positive linear relationship between plant population and yield showed that for every 1% loss in plant stand below the optimum range of 60 000–65 000 plants/ha, there is a 0·72-0·74% loss in grain yield respectively. Control measures would be economically justified with only a 2·3% reduction in plant stand (assuming $20/ha for cost of control and $150/tonne for maize).     

Effects of a range of fungicides used to control rust (Uromyces viciae-fabae) on spring-sown field beans (Vicia faba) in the UK

In two years a range of fungicides was used to control rust (Uromyces viciae-fabae) on spring-sown field beans (Vicia faba). In 1984 fenpropimorph, maneb, mancozeb, maneb plus mancozeb, propiconazole, thiram, triadimefon and zineb-polyethylene thiuram disulphide plus tridemorph were applied once or twice and compared with no fungicide. In 1985 the experiment was repeated with the addition of benodanil. In 1984 there was very little rust or other foliar disease and the effects of treatments on yield were small. In 1985 rust was first found in late June and became severe on untreated plots in August. All the fungicides reduced the incidence of rust but the amount of control differed with frequency of application and on different dates of disease assessment. In 1985 chocolate spot (Botrytis fabae) also became severe in late August. All the fungicides reduced chocolate spot but maneb plus mancozeb was the most effective. In 1985 yields were increased from 5 · 6 to 7 · 7 t/ha by maneb plus mancozeb applied once. Other fungicides gave smaller yield increases. Yield increases given were attributable mainly to control of rust but partly to control of chocolate spot. Yield increases given by non-systemic fungicides came mainly from increases in the weight of individual grains; those yield increases given by systemic materials came, in addition, from better pod retention.     

Effect of trifluralin,pronamide, haloxyfop-p methyl,propaquizafop, and isoxaben on weed control and oilseed rape yield in Iran

In order to investigate the effect of trifluralin, pronamide, haloxyfop-p methyl, propaquizafop and isoxaben on weed control and oilseed rape yield, a two year field experiment was conducted at Darab, Iran, during 2004–2005 and 2005–2006 growing seasons. Herbicides reduced weed biomass compared with the weedy check. In 2004–2005, at 16 WAP (weeks after planting), application of trifluralin plus propaquizafop plus isoxaben at 1200 + 200 + 250 g a.i./ha and trifluralin plus haloxyfop-p methyl plus isoxaben at 1200 + 100 + 500 g a.i./ha provided best control (80%) of wild mustard (Sinapis arvensis L.), compared to other treatments. At 8 and 16 WAP, wild mustard control decreased to 47 and 42%, respectively, when trifluralin was applied alone at 1400 g a.i./ha. In 2005–2006 at 16 WAP, maximum reduction in wild mustard biomass (82%) was achieved with trifluralin plus propaquizafop plus isoxaben at 1200 + 200 + 250 g a.i./ha. In both years, all herbicide treatments controlled fumitory (Fumaria officinalis L.) 64–96%. In 2004–2005, at 16 WAP, wild oat (Avena fatua L.) biomass reduction by trifluralin plus propaquizafop plus isoxaben at 1200 + 200 + 250 g a.i./ha was 95%. In 2005–2006, at 8 and 16 WAP, minimum biomass reduction of wild oat (37–53%) was observed with trifluralin at 1200 and 1400 g a.i./ha. In both years, at 8 and 16 WAP, the most effective herbicide treatments were trifluralin plus propaquizafop plus isoxaben and trifluralin plus haloxyfop-p methyl plus isoxaben regardless of the dose applied and provided maximum reduction in total weed biomass (77–89%) compared to other treatments. Results of both years showed that all herbicide treatments increased oilseed rape grain yield as compared with the weedy check but percentage of oil was not affected by various herbicide treatments. Maximum grain yield was obtained with trifluralin plus haloxyfop-p methyl plus isoxaben at 1200 + 100 + 500 g a.i./ha.     

Controlled-release insecticide granules, compared with other soil insecticides, for use against the termite, Macrotermes natalensis Haviland, in the establishment of Eucalyptus plantations

Following the banning of DDT and dieldrin, and pending the withdrawal of other organochlorine insecticides in many countries, there is a need to find alternative treatments against termites for the establishment of Eucalyptus forestry plantations. Controlled-release granules (CRG) of carbosulfan, carbofuran and phorate were nearly as effective as chlordane emulsifiable concentrate (0·6 g a.i./tree) in reducing attack on Eucalyptus grandis W. Hill ex Maiden by Macrotermes natalensis Haviland. The optimum application rate of CRG formulations was 1·0 g a.i./tree mixed with the surrounding soil at planting out. Changes in granule size and release rate had no discernable effect on the efficacy of the granules, nor was there any advantage in incorporating part of the dose in the seedling planting medium. Chlorpyrifos CRG was significantly less effective in protecting the trees. There was evidence that under dry soil conditions phorate CRG was ineffective. Of 11 other non-controlled-release insecticides tested, alphamethrin suspension concentrate at 0·1 g a.i./tree was the only non-organochlorine material as effective as the CRG formulations.     

Chemical control of sorghum head bugs (Hemiptera: Miridae)

Eight contact and three systemic insecticides, and an enriched neem extract were tested for the control of sorghum head bug, Calocoris angustatus Leth. at the ICRISAT Center. The insecticides were applied at the complete-anthesis and milk stages (at 500 1/ha) with a knapsack sprayer. On the basis of effectiveness of head bug control, grain yield and 1000-grain mass, carbaryl (at 500 g a.i./ha) was the most effective insecticide followed by fenvalerate (at 50 g a.i./ha), and chlorpyrifos (at 250 g a.i./ha). Among the systemic insecticides, demeton-S-methyl (at 250g a.i./ha), was the most effective. Demeton-S-methyl and dimethoate were also effective for the control of other head bug species—Eurystylus bellevoyei Put. and Reut. and Campylomma sp. Plots sprayed with demeton-S-methyl gave higher grain yields than those treated with carbaryl, which was the best contact insecticide. Two sprays of carbaryl (at 500g a.i./ha) applied at the complete-anthesis and milk stages have been found to be effective for head bug control. Dichlorvos, fenitrothion and monocrotophos were highly phytotoxic and resulted in burning and drying of entire leaves. Dimethoate resulted in a slight drying of leaf tips and margins.     

The effect of seed treatment with chlormequat on the control of barley leaf stripe, Drechslera graminea (Rabenh. et Schlecht.) Shoemaker, with fungicides

Seed of winter barley, naturally infected with Drechslera graminea (Rabenh. et Schlecht.) Shoemaker (Helminthosporium gramineum Rabenh.), was treated with chlormequat (chlormequat chloride; CCC) (2·5 g a.i./kg seed) alone or mixed with fungicides (thiram plus carboxin; mancozeb; thiophanate-methyl plus maneb; carbendazim; methfuroxam; tolchlofosmethyl; procymidone; nuarimol) before being sown by hand in a randomized block field trial with four replicates. There was no reduction in the number of plants that emerged. CCC alone did not reduce the incidence of barley leaf stripe. However, all the fungicides, apart from thiram plus carboxin, showed increased activity when mixed with CCC, as shown by a reduction either in the number of plants infected, or in the percentage of empty ears. No lodging was observed in the trials: not only CCC alone, but the fungicides also, both alone and in the presence of CCC, significantly reduced the lengths of the first and second internodes. Treatment of winter barley seed with mixtures of CCC and fungicides appears to be a promising method for control of barley leaf stripe and for reduction of lodging.     

Control of Bromus species in winter barley in England using EPTC

EPTC was tested in glasshouse and field experiments for its potential as a herbicide to control Bromus species in winter cereals. Bromus hordeaceus, Bromus commutatus, Bromus pectinatus and Bromus sterilis were all selectively controlled in barley by EPTC. Winter wheat was found to be susceptible but winter barley tolerated doses up to 2·0 kg a.i./ha. The barley cultivar Sonja was more resistant than both Athene and Maris Otter. In the first field trial, 1·0 kg a.i./ha EPTC reduced B. sterilis plant numbers by 75% giving a barley yield increase of 2·84 t/ha. In the following year 2·0 kg a.i./ha reduced B. sterilis numbers by 54% and increased yield by 1·75 t/ha.     

Effects of Fungicide and Rate of Application on the Development of Isolates of <Emphasis Type="Italic">Polyscytalum pustulans</Emphasis> Resistant to Thiabendazole and on the Control of Skin Spot

Resistance to thiabendazole, sometimes of varying degrees, has occurred in a number of fungal species causing diseases of potato tubers, including skin spot caused by Polyscytalum pustulans. The effect of applying a range of concentrations of thiabendazole, imazalil or a formulated mixture of thiabendazole and imazalil on the development of isolates of P. pustulans partially or fully resistant to thiabendazole and on the control of skin spot over a number of successive generations of seed potato multiplication was examined in a series of experiments over 3 years. Seed tubers were inoculated with a sensitive, partially resistant or fully resistant isolate in the first year of an experiment and combinations of fungicide and a range of concentrations were applied to the seed tubers annually before planting over two or three successive generations. Immersing seed tubers inoculated with the partially resistant isolate in a relatively high concentration of thiabendazole, 0.7 g a.i. l^-1, did not result in the development of fully resistant isolates. Moreover, the effect of all fungicides in controlling eye contamination and skin spot did not differ between partially and fully resistant isolates. For seed tubers inoculated with the sensitive isolate, applying thiabendazole resulted in the occurrence of resistant isolates on first-generation daughter tubers, but the effect of fungicide concentration on the frequency of resistant isolates, partially or fully resistant, was inconsistent. In one experiment, the highest frequency of resistance was found at the greatest concentration, 0.4 g a.i. l^-1, but, in the second experiment, the frequency was unaffected by the concentration of thiabendazole. On second-generation daughter tubers derived from thiabendazole-treated seed tubers, virtually all isolates were resistant and the frequency of partially and fully resistant isolates was similar to that in the first generation. Applying a mixture of thiabendazole and imazalil to seed tubers inoculated with a sensitive isolate resulted in the development of some resistant isolates in the first year but the frequency did not generally increase with successive applications of the mixture. A mixture of thiabendazole and imazalil, and imazalil alone gave similar control of eye contamination when applied at equivalent concentrations. However, increasing the concentration of imazalil from 0.1 to 0.7 g imazalil l^-1 did result in an increasing impairment of plant growth, but the deposits achieved within that range of concentrations were greater than that recommended by the manufacturer. These results demonstrate that control of P. pustulans by thiabendazole, imazalil and a mixture of thiabendazole and imazalil applied at a range of concentrations was similar for isolates partially or fully resistant to thiabendazole.     

Increased severity of Rhizoctonia root rot in sugar beet treated with systemic insecticides

The systemic insecticides aldicarb 15G (15% granules) at 2·6 kg active ingredient (a.i.)/ha and phorate 1OG (10% granules) at 1·7 kg a.i./ha, applied as side dressings about 1 month after planting in 1979 and 1980, significantly increased the severity of root rot, caused by Rhizoctonia solani Kühn, in sugar beet (Beta vulgaris L.). Carbofuran 10G (10% granules) at 2·2 kg a.i./ha also increased root rot, but not significantly. Numbers of harvestable roots were reduced by all treatments but significantly by phorate only. Both aldicarb and phorate were slightly fungistatic to R. solani when the pathogen was grown on potato-dextrose agar incorporating 0·5, 5·0, and 25 μg a.i./ml. Trichoderma sp., a potential antagonist of Rhizoctonia, was slightly inhibited by aldicarb and phorate initially, but soon overcame the effect. Thus, the increase in disease severity in the field may be attributable to some metabolic or physiological effect of the chemicals either on the host or on the infection process of the pathogen. Indiscriminate use of these insecticides should therefore be avoided in areas where root rot is prevalent but where insects are not a problem.     

Phytotoxicity of isazophos,lindane and heptachlor to sorghum applied as in-furrow and broadcast-incorporated treatments

Isazophos applied as an in-furrow spray at 0·5, 0·75 and 1·0 kg a.i./ha (4·65, 6·98 and 9·3 g a.i./100 m of row) reduced the establishment of Yates NK 212 sorghum by 37, 61 and 75% respectively. Similarly, heptachlor at 1·12 kg a.i./ha (10·42 g a.i./100 m of row) and lindane at 0·29 kg a.i./ha (2·7 g a.i./100 m of row) reduced establishment by 24 and 57% respectively. Heptachlor and isazophos, applied at the same rates but as broadcast-incorporated sprays and the lowest rate of isazophos applied as an in-furrow spray (0·25 kg a.i./ha, 2·33 g a.i./100 m of row) were not phytotoxic.     

Evaluation of in-furrow fungicide treatments to control rhizoctonia root rot of wheat

The efficacy of eight fungicides, placed in-furrow at sowing, to reduce rhizoctonia root rot and increase yields of wheat was examined in glasshouse and field experiments. Under glasshouse conditions three of the fungicides, coated on clay granules at a rate equivalent to 400 g a.i. ha⁻¹, reduced root rot of wheat grown in soil inoculated with Rhizoctonia solani. None of the chemicals stimulated growth of wheat in the absence of disease, but three retarded growth. Experiments at six sites with different soil types and rhizoctonia risk in north-west Victoria, Australia, showed that the fungicide-coated granules were generally ineffective at reducing both incidence and severity of rhizoctonia root rot of wheat. However, tebuconazole was effective at two sites and at one of these flutriafol, RH-7592, cyproconazole and diniconazole also reduced disease severity. Yields were increased by 51% with tebuconazole at one site, by 40% with diniconazole at another and by between 23 and 30% with RH-7592, diniconazole, flutriafol and flutolanil, at a third site.     

Activities of azoxystrobin and difenoconazole against Alternaria alternata and their control efficacy

Tobacco brown spot caused by Alteraria alternata is a devastating disease of tobacco worldwide. In this study, we reported the effects of a strobilurin fungicide azoxystrobin and a sterol inhibitor difenoconazole on mycelial growth, spore germination, and control of brown spot. Both mycelial growth and spore germination bioassay results showed that sensitivity of A. alternata to difenoconazole was significantly lower than that to azoxystrobin. Azoxystrobin and the compound of azoxystrobin plus difenoconazole provided excellent control efficacy on tobacco brown spot in field. Disease control efficacies for three sprays of azoxystrobin at doses of 0.094, 0.19 and 0.28 Kg a.i./ha, of azoxystrobin plus difenoconazole at 0.15, 0.22 and 0.29 Kg a.i./ha, and of difenoconazole at 0.12 Kg a.i./ha were between 86.00% and 89.67%, between 86.14% and 89.23%, and between 55.14 and 58.41%, respectively. No phytotoxic symptoms were observed for the fungicides in field. These fungicides could potentially be used for brown spot control in tobacco.     

苦瓜双色平脐蠕孢叶斑病病原菌的生物学特性及其抑菌药剂筛选

为了明确苦瓜双色平脐蠕孢叶斑病菌（Bipolaris bicolor）的生物学特性及其对杀菌剂的敏感性,研究了不同培养条件对该病原菌菌丝生长的影响,并测定了10种杀菌剂对该病原菌的抑制作用。结果表明：该病原菌菌丝生长最适温度为25~30 ℃,最适pH范围为6~7,适宜培养基为马铃薯蔗糖培养基（PSA）和玉米粉培养基（CMA）,持续黑暗和光暗交替有利于菌丝生长;不同碳源和氮源对菌丝生长的影响差异显著,其中葡萄糖和蛋白胨分别为最适碳源和氮源,菌丝生长致死温度为45 ℃。250 g/L苯醚甲环唑乳油毒力最强,EC₅₀为0.0233 mg/L,其次为250 g/L吡唑醚菌酯悬浮剂、20%抑霉唑水乳剂和50%嘧菌环胺水分散粒剂。     

航天诱变小麦衍生系对主要真菌病害的抗性

为了解航天诱变小麦后代衍生系对条锈病、白粉病和赤霉病的抗性特点,进而从中筛选出高抗且多抗的抗源材料,分别设置了CYR32和CYR33的混合条锈病鉴定圃、关中混合菌系的白粉病鉴定圃、强致病性混合小种CH1的赤霉病鉴定圃。鉴定结果表明,在供试的74份衍生系中,在条锈病方面,感病选系27个,成株期抗病选系30个,全生育期抗病选系17个;在白粉病方面,高感选系13个,中感选系38个,中抗选系19个,高抗选系4个;在赤霉病方面,高感选系33个,中感选系33个,中抗选系8个。三种病害抗性综合鉴定发现,兼抗条锈病和白粉病的选系有23个,其中包括高抗条锈病、高抗白粉病但高感赤霉病的选系3个,中抗条锈病、中抗白粉病但中感赤霉病的选系10个,兼抗条锈病和赤霉病的选系5个;筛选出1个对三种病害都表现中抗特征的选系SPW57-35。这些高抗和多抗突变体衍生系可作为小麦新型抗源材料。     

Can grain growers and agronomists identify common leaf diseases and biosecurity threats in grain crops? An Australian example

The Australian grains industry relies upon growers and agronomists to be aware of pests and diseases in their crops and to notify their local State Department of Agriculture when they suspect an incursion of a high priority pest (HPP). This raises the question “Are growers and agronomists, within the Australian grains industry, able to meet this expectation?” A training needs analysis was undertaken to determine the capacity of growers and agronomists to identify three endemic diseases (powdery mildew in barley, stripe rust in wheat and blackleg in canola) in their crops. Their knowledge of the top four-biosecurity threats to the Australian grains industry (Karnal bunt, Khapra beetle, barley stripe rust and Russian wheat aphid) was also determined. Benchmarks for successfully identifying these diseases were set beforehand at 70% of growers and 80% of agronomists; participants’ ability to identify these endemic diseases in crops met these benchmarks. However, their ability to recognise blackleg in canola was significantly lower than for the two cereal foliar diseases. There was a significant correlation of region with these capabilities, with a greater proportion of participants in Western Australia (WA) recognising powdery mildew in barley than in Eastern Australia (EA). In contrast, a greater proportion of participants in EA were able to identify stripe rust of wheat than in WA. The education levels of participants corresponded with their ability to identify blackleg in canola. Participants’ knowledge and awareness of symptoms and signs associated with the top four biosecurity threats were well below expectations; fewer than half of the participants answered questions on these four HPPs. Gender, age and educational level did not correlate with the participants’ knowledge and awareness of the four HPPs with the exception of Karnal bunt. Participants with a higher level of education had significantly more knowledge of symptoms associated with Karnal bunt than did participants with lower levels of education. The use of diagnostic services by the grains industry participants is a vital component of general surveillance. This survey showed that use of these services by growers was significantly lower than by agronomists. Awareness of the National Exotic Plant Pest Hotline and GrainGuard was significantly lower than other diagnostic services for both growers and agronomists. Diagnostic services need to be promoted further to increase awareness and use by growers and agronomists. Correct diagnosis of disease and pest symptoms is vital for the biosecurity of the grains industry.     

Effects of sulfosulfuron soil residues on barley (Hordeum vulgare), sunflower (Helianthus annuus) and common vetch (vicia sativa)

The phytotoxicity and sensitivity of succeeding crops to the new sulfonylurea, sulfosulfuron, have been reported although there is insufficient data on the phytotoxic effect of field soil residues. Growth chamber bioassays were conducted to detect the presence of residues in soil samples previously treated with sulfosulfuron at the recommended rate and double rate (20 and 40 g a.i./ha) that could affect the succeeding crop. Soil samples were collected between 7 and 9 months after sulfosulfuron application in field selectivity assays at nine different locations in Northern and Central Spain. The bioassay test species were barley (Hordeum vulgare L.) ‘Graphic’, sunflower (Helianthus annuus L.) ‘Albasol’ and common vetch (Vicia sativa L.) ‘Neska’, typical crops grown in rotation with wheat (Triticum aestivum L.) in this area. Sulfosulfuron residues did not affect barley and common vetch, but inhibited shoot length, root length and root dry weight of sunflower seeded into some soils treated with the 2× rate (40 g a.i/ha) 9 months earlier.     

大豆苗后除草剂灭草松与精喹禾灵联合防除马唐、反枝苋的研究

在温室内采用单轴等效线法测定大豆苗后除草剂灭草松与精喹禾灵联合作用的结果表明 ,灭草松与精喹禾灵混用对马唐有增效作用 ,随着灭草松的剂量从 0增加到 60 0 ga .i./hm2 ,精喹禾灵抑制马唐 90 %的有效剂量 (ED90 )随之从 14.88ga .i./hm2 下降到 4 .89ga .i./hm2 。当灭草松与精喹禾灵以低剂量混用时 ,对反枝苋表现为拮抗作用 ,而两者以高剂量混用时 ,表现为增效作用