TW201124084A - Noxious organism controlling composition and method for controlling the noxious organism - Google Patents

Abstract

To obtain a noxious organism controlling composition enhanced in the controlling effect on noxious insects living in soil and/or seeds and simultaneously enhanced in a controlling effect on infectious disease damage in the soil and/or the seeds. The noxious organism controlling composition contains at least one kind of organic phosphorus compound selected from the group consisting of S-sec-butyl O-ethyl 2-oxo-1,3-thiazolydin-3-ylphosphonothioate, O-ethyl-S-n-propyl(2-cyanoimino-3-ethyl-imydazolidin-1-yl)phosphonothiolate, and S,S-di-sec-butyl O-ethyl phosphorodithioate and at least one kind of bactericidal agent selected from the group consisting of Fluazinam, Benomyl, Tolclofos-methyl, Metalaxyl, Captan, Iprodione, Chlorothalonil, Dazomet, Hymexazole, Flutolanil, and Validamycin as active ingredients.

Description

201124084 VI. Description of the Invention: [Technical Field to Be Invented by the Invention] The present invention relates to a pest control composition which effectively simultaneously prevents various pests and pests. [Prior Art] Thio-sec-butyloxy-ethyl 2 -carbonyl· 1 , 3 -thiazolidinate is a compound disclosed in Patent Document 1. Oxy-ethyl-sulfury 2-cyanoimido-3-methyl-imidazolidine-1-yl)thiophosphate {The disclosed compound. S, S-di-sec-butyloxy-ethyl 2 The compound disclosed in Patent Document 3. These are known organophosphorus compounds which are active ingredients of insecticidal nematodes. However, when a specific organophosphorus compound and a specific bactericide are used, the effects of the multiplication of the pests in the soil and/or the seed, and the soil and/or the seed disease are exerted. Patent Document 1: U.S. Patent No. 4,590, 182, Patent Document 2: U.S. Patent No. 5,405, 591, Patent Document 3: U.S. Patent No. 4, 5,037, the disclosure of which is hereby incorporated by reference. Pests such as cockroaches infested in soil i, and soil and/or seed-infected plant diseases are more individually controlled than individual ones, and are more effective in controlling the effects of both sides of various plant diseases -3-yl thiophosphine: n-propyl ( Patent Document 2 thiophosphoric acid, killing, killing and unknown combination in the control of both invasive plants and/or seeds, and the harmful organisms-5-201124084 control agent. The solution of the problem is solved by the inventors As a result of the evaluation of the above-mentioned problems, it has been found that the above-described effects can be obtained by combining a specific organophosphorus compound with a specific bactericidal agent. The present invention has been made up of the following points. Containing at least one selected from the group consisting of thio-sec-butyloxy-ethyl 2-carbonyl-1,3-1,3-thiazolidin-3-ylthiophosphonate, oxy-ethyl-thio-n-propyl (2-cyanide) Imino-3-methyl-imidazolidin-1-yl) Phosphate esters and organophosphorus compounds in groups of S,S-di-sec-butyloxy-ethyl dithiophosphoric acid, and at least one selected from the group consisting of Fluazinam, Benomyl, and methyl Tolclofos-methyl, Metalaxyl 'Captan', Iprodione, Chlorothalonil, Dazomet, Hymexazole The bactericidal agent grouped by Flutolanil and Validamycin is a pest control composition characterized by an active ingredient. 2. The above-mentioned organophosphorus system is included in the pest control composition described in the above 1. The content ratio of the compound to the above bactericide is 1:1 to 10000: 3, and contains at least one selected from the group consisting of thio-sec-butyloxy-ethyl 2 carbonyl-1,3-thiazole pyridine-3 -ylthiophosphonate, oxy-ethyl thio-n-propyl (2-cyanoimido-3-methyl-imidazolidine-1-yl)thiophosphate and S,S-di-sec-butyl -6 - 201124084 Organophosphorus compounds in groups of oxy-ethyl dithiophosphoric acid, and at least one selected from the group consisting of Fuzinam (Benomyl), Tolclofos-methyl 'Metalaxyi, Captan, Iprodione, Chlorothalonil, Dazomet, A bactericide in which a group of Hymexazole, Flutolanil, and Validamycin are active ingredients acts as a pest control agent for harmful organisms. 4. The method for controlling a pest according to the above 3, wherein the organic phosphorus compound is allowed to act simultaneously with the sterilizing agent, or the organic phosphorus compound and the sterilizing agent are acted upon, and then another effect is applied. 5. The method for controlling pests according to the above 3 or 4, wherein the ratio of the ratio of the organophosphorus compound to the bactericide is from 1:10000 to 10,000:1. 6. The method for controlling a pest according to any one of the above 3 to 5, wherein the concentration of the active ingredient is from 0.1 to 1000 ppm. 7. The pest control method according to any one of the above 3 to 6, wherein the harmful organism is a pest inhabiting the soil and/or the seed. 8. The pest control method according to any one of the above 3 to 6, wherein the pest is a pest inhabiting the soil and/or the seed. 9. In the method for controlling a pest according to any one of the above 3 to 9, the "harmful plant parasitic nematode", the pest control method according to any one of the above 3 to 6, 201124084 At least one species of the nematode is selected from the group consisting of nodule nematodes, golden nematodes, root rot nematodes, Neisseria candida, Strawberry bud nematodes, and Pine wood nemotode. The method for controlling a pest according to any one of the items 3 to 10, wherein the organophosphorus compound and the bactericide are treated in soil and/or seed. EFFECT OF THE INVENTION According to the present invention, there is provided a novel pest control composition and a control method for simultaneously improving the effects of controlling pests inhabiting soils and/or seeds, and controlling the effects of soil and/or seed infectious diseases. BEST MODE FOR CARRYING OUT THE INVENTION For thio-sec-butyloxy-ethyl 2-carbonyl-1,3-thiazolidin-3-ylthiophosphonate, optical isomers exist, except for racemates. Contains (·) and (+) bodies. The (R,S)·thio sec-butyloxy-ethyl 2-carbonyl-1,3-thiazolidin-3-yl thiophosphonate of the racemate is known generally as Fosthiazate. Compound. Oxy-ethyl-thio-n-propyl (2-cyanoimido-3-methyl-imidazolidine-1-yl)thiophosphate is also present as an optical isomer, including (-) in addition to the racemate Body and (+) body. S,S-di-sec-butyloxy-ethyl dithiophosphate is a compound known generally as cadusafos. 201124084 Fluazinam, Benomyl, Tolclofos-methyl, Meta 1 axy丨, Captan, Ipro di οne ), Chlorothalonil, Dazomet, Hymexazole, F 1 utο 1 ani 1 , Validamycin are all pesticides , a compound described in The pesticide Manual (13th edition; BRITISH CROP PROTECTION COUNCIL). The mixing ratio of the above organophosphorus compound and the bactericide is usually 1: 10,000 to 10,000: 1, and preferably 1: 1000 to 1000: i. The composition of the present invention contains a supplement other than the active ingredient. The compounding ratio of the active ingredients is from 0. 5 to 75% by weight. The auxiliary agent may, for example, be a carrier, an emulsifier, a suspending agent, a dispersing agent, a developing agent, a penetrating agent, a wetting agent, a tackifier or a stabilizer, and may be appropriately added as needed. The carrier can be classified into a solid carrier and a liquid carrier, and examples of the solid carrier include animal and plant powders such as starch, activated carbon, soybean powder, wheat flour, wood flour, fish meal, and milk powder, talc, clay, bentonite, and calcium carbonate. And mineral powders such as zeolite, diatomaceous earth, carbon white, clay, alumina, and sulfur powder, and examples of the liquid carrier include alcohols such as water, methanol, and ethanol, acetone, methyl ethyl ketone, and the like. Ethers such as ketones, di ntan and tetrahydrofuran, aliphatic hydrocarbons such as kerosene and kerosene, and aromatic hydrocarbons such as xylene, trimethylbenzene, tetramethylbenzene, cyclohexane and solvent naphtha, and chloroform Halogenated hydrocarbons such as chlorobenzene, acid amides such as dimethylformamide, esters such as ethyl acetate and glycerides of fatty acids, nitriles such as acetonitrile, and dimethyl sulphide-9- 201124084 Such as sulfur compounds. Various surfactants can be used as emulsifiers, suspending agents, dispersing agents, developing agents, penetrating agents, and wetting agents. In addition, other pesticides such as insecticides, acaricides, nematicides, fungicides, antiviral agents, attractants, herbicides and plant growth regulators can be mixed and used as needed. Excellent results. The composition of the present invention can be formulated into various types such as emulsions, powders, granules, granules, troches, hydrating agents, liquids, aerosols, pastes, suspensions, dry suspensions, and microcapsules. Among them, emulsions, microgranules, hydrating agents, liquid powders, granules, and lozenges are preferred, and emulsions, microgranules, hydrating agents, and liquids are preferred. A suitable compounding ratio in the emulsion is 5 to 75 parts by weight, the carrier is 90 to 10 parts by weight, and the surfactant is 5 to 15 parts by weight. Further, a suitable compounding ratio of the powder, the granules and the tablet is from 0.1 to 10 parts by weight, the carrier is from 85 to 99 parts by weight, and the surfactant is from 0.5 to 5 parts by weight. In practice, when such a preparation is used, it can be used as it is, or diluted with a diluent such as water to a predetermined concentration. The effective concentration of the composition of the present invention is generally from 0.1 to 1000 ppm, more preferably from 1 to 1000 ppm. The concentration of these active ingredients may be appropriately changed depending on the type of the preparation, the method of use, the purpose, the period, the place, and the occurrence state of the pest, etc., and the amount of use per unit area is about 1 〇a, and the active ingredient compound is used. From 1 to 5000 g, preferably from 10 to 1,000 g. However, in special cases, these ranges may also be exceeded. The method of using the composition of the present invention may, for example, be a soil mixing treatment, a planting treatment, a gutter treatment or a perfusion treatment, or an immersion treatment for seeds or the like, and a powder coating treatment -10-201124084. In the present invention, in addition to the method for treating the composition of the present invention to a pest, a method of simultaneously treating the organophosphorus compound and the bactericide to a pest, and treating one of the organophosphorus compound and the bactericide to the pest, Another method of treating another agent in a pest. Examples of the pest to which the present invention is applicable include plant parasitic nematodes, isopods, 'coleoptera pests, lepidopteran pests, gastropods, orthoptera pests, plant parasitic mites, damselfish pests, and double wings. Various pests or various plant diseases such as target pests, Hymenoptera pests, Hymenoptera pests, Odonata pests, and Isoptera pests. In particular, the present invention is effective for controlling pests inhabiting soils and/or seeds. Examples of the pests that inhabit the soil and/or the seed include pests such as agricultural horticultural crops and trees, pests such as agricultural horticultural crops or trees, and pests. For example, the above-mentioned plant parasitic nematodes, isopods, coleopteran pests, lepidopteran pests, gastropods, Orthoptera pests, and plant parasitic mites. Wherein the invention is most effective for controlling plant-parasitic nematodes. Specific examples of various pests to which the present invention is applicable are shown below. Examples of plant-parasitic nematodes include nodule nematodes such as Meloidogyne inc〇gnita; golden nematodes such as Globoderarostochiensis; and P raty 1 enchuspenetrans; Root rot nematodes; Neisseria candida; Nothotylenchus acris (Strawberry bud nematodes) and Pine wood nemotode (Pine wood nemotode). Further, the 'equipment type' may be, for example, a bandit, a grass worm, or the like. -11 - 201124084 As a coleopteran pest, for example, corn rootworms such as western corn rootworm and southern corn rootworm: golden chafers such as gold-copper tortoises and ginseng tortoises; maize weevil and rice water elephants Nematodes such as larvae, locust leaf weevil, mung bean weevil, etc.; black powderworms such as yellow mealworms and quarantine worms, yellow stalked melons, yellow stalks, and potato beetles (Leptinotarsa decemlineata) Golden flower worms: thief species; ladybugs such as the 28-star ladybug; brown powder stupid; big valley stupid; long stupid; brown poisoned worm, etc. As a lepidopteran pest, for example Noctuidae such as Spodoptera litura, Zygomycosis, Daphnia, Spodoptera exigua, and Brassica californica; nocturnal moths such as cutworm, budworm, genus, genus, and genus Classes; aphids, rice leafworms, European corn snails, Parapediasia teterrella, Notarcha derogata, Plodia interpunctella, etc.; butterfly species such as white butterfly; genus Corydalis, Peach worm, and apple moth Leaf moth, fruit moth, etc. Classes; the moths of the genus Peach genus; the genus Moths of the genus Gypsy, the genus Xanthophylls, and the genus Moth, such as the diamondback moth. Examples of the gastropods include snails, snails, and the like. Examples of the Orthoptera pests include cockroaches, cockroaches, German cockroaches, black brown cockroaches, American cockroaches, brown cockroaches, and oriental cockroaches. Examples of the plant parasitic mites include, for example, two-spotted spider mites, red stalks, citrus leaf mites, and root mites. Examples of the pests of the common horses include the southern yellow horse, the onion horse, and the flower horse. -12- 201124084 As a dipteran pest, for example, Culex pipiens, Culex pipiens pallens, house mosquitoes, house flies, flies, flies, flies, etc. Flower flies, fruit flies, fruit flies, moths, mites, mites, ticks, larvae, etc., in the summer flies, flies, and onion flies, etc. Examples of the pest include bees such as mites, wasps, ant bees, and yellow-winged bees. Examples of the cryptic wing pests include human mites and the like. Examples of the target insects include human lice and shame. Examples of the isofoptera pest include, for example, yellow-breasted white mites and house termites. As various plant diseases to which the present invention is applicable, for example, soil and/or seed infectious plant diseases can be mentioned. Specifically as described below. Various diseases caused by the Rosalinia bacterium, such as Rhizoctonia solani; Rhizoctonia solani; Rhizoctonia solani; Beet, Pre-former, Pre-branched, Gherkin , green pepper, duck bud, buckwheat, delphinium 'Ohki's seedling blight (Rhizoctonia solani); duck celery, Korean cabbage blight (Rhizoctonia solani) •, carrot root rot (Rizoctonia solani Rhizoctonia solani; spinach, cabbage rotani (Rhizoctonia solani); burdock black spot disease (Rhizoctonia solani); radish crack browning (root rot) (Rhizoctonia) Solani)

Liromyces h ο 1 w a y i caused by Uromyces bacteria; -13- 201124084

Various diseases caused by Pythium bacteria, such as Pythium debaryanum: Pythium debaryanum; pilosula, cucumber, anterior, green pepper, cantaloupe, melon, watermelon, white melon, pumpkin Pythium vexans: Pythium aphanidermatum: Pythium aristosporum; Pythium ulitimum;

Various diseases caused by Fusarium bacteria, such as tulip root rot (Fusarium ox. ysporum); Fusarium oxysporum; Fusarium oxysporum; potato, wilting disease (Fusarium oxysporum); cucumber, sweet potato vines (Fusarium oxysporum); Basil's disease (Fusarium solani); artichoke, hot rot (Fusarium oxysporum);

Various diseases caused by Phytophthora bacteria, such as Phytophthora cinnamomi: Phytophthora cactorum; green pepper, Basili, gerbera, perennial star, sea otter, African cockroach, Phytophthora capsici; Phytophthora fragariae;

Various diseases caused by Verticillium bacteria, such as Verticillium dahliae; Verticillium dahliae;

Root rot of beet caused by Thanatephorus

Thanatephorus cucumeris ); -14- 201124084

Rhizopu necans caused by Rhizopu bacteria »

Penicillium caused by penicillium (PeniciUium cyclopium);

Plasmodiophorabrassicae of rapeseed vegetables such as cabbage, cabbage, etc. caused by Plasmodiophora;

Spongospora subterranea caused by Spongospora bacteria;

Rosellinia necatrix caused by rosellinia; fruit trees, flowers, and tea;

Sclerotiumrolfsii caused by bacteria, amaranth, coltsfoot, scouring, soybean, chrysanthemum, and green pepper caused by Sclerotium;

Colletotrichum acutaum caused by Colletotrichum bacteria;

Polysaccharosis of sugar beet caused by Polymyxa (Polymyxa betae medium);

Botritis squamosa caused by Botritis bacteria;

Helicobasidium disease caused by Helicobasidium bacteria (Helicobasidium mompa);

Ceratocystis imbriata caused by Ceratocystis;

Monosporascus cannonballus caused by Monosporascus; -15- 201124084

Thielaviopsis basicola caused by Thielaviopsis;

Potato black spot (Thantatporus cucumeris ) caused by Thantatporus ;

Thanatephorus cucumeris caused by Thanatephorus bacteria;

Gibberella fujikuroi caused by Gibberella bacteria;

Sterpomyces scabies caused by Sterpomyces bacteria; and rice leaf fever (Pyricularia oryzae) caused by Pyricularia bacteria; etc. In addition, the present invention is applicable to many soil infectious or seed infections as exemplified Sexual disease. The compositions and methods of the present invention have a synergistic effect in controlling pests. This effect is unpredictable by the respective agents to prevent the characteristics of various pests and diseases. It can be said that the effectiveness of the present invention significantly enhances the pest control effect, particularly the pest resistance in the soil, and has the effect of giving immediate effect, compared to the use of each of the medicines alone. [Embodiment] The following is a description of the present invention Example-16 - 201124084 [Table 1] General name or chemical name Compound No. [I] Organophosphorus compound Fozei Ia Oxygen-ethyl-thio-n-propyl (2-Cyminoimido-3-methyl-imidazolidine-1-yl)thiophosphate: a compound described in U.S. Patent No. Ib 5405961, chlorophyll Ic [Π] bactericide, gibberidine II-a Free lazy to Il-b methyl chlorpyrifos II-c halal Il-d cappdan Il-e yipu with Il-f tetrachloroisophthalene ng mailong Il-h killing lining Il-i Fudaning N-,i vilimycin Il-k

S -17- 201124084 Test Example 1 In the chemical solution of the specified concentration, 200 to 25 larvae of the second phase of the nematode, Nematode, were immersed and stored in a constant temperature room at 25 °C for 24 hours. Investigate the total number of A. tumefaciens (A) in the liquid medicine and the number of unactive activities (B) in the liquid for 15 seconds. In addition, the number of investigations (A') of the control area using distilled water instead of the drug solution and the number of unactive activities (B,) of 15 seconds were investigated. From this, 运动' is determined by the following equation. The results are shown in Tables 1 to 12. Movement inhibition rate (%) = [1-{(1-Β/Α)/(Β, /Α,)}]χ1〇〇 In addition, the theory of motion inhibition rate (%) is calculated by the Corby formula. When the exercise inhibition ratio (°/β) is higher than the theoretical 値 (%), the harmful biological control composition of the present invention has a synergistic effect on the control of nematodes. The theory at this time (%) - 倂 is expressed in (1) to (12). [Table 2] The obstruction rate of No. 2 elegans nematode (%) Π [-a] lOppm 5.Oppm 2.5ppm 1.25ppm 0.63ppm Oppm [ΙΙ-e] lOOOOppm 100.0 (98.0) 93.6 (92.5) 93.5 (84.3 56.4 (37.9) 54.8 (37.9) 10.3 Oppm 97.8 91.6 82.5 30.8 30.8 0 -18- 201124084 [Table 3] The obstruction rate of the nodule nematode in the second table (%) Γ] [-a] lOppm 5. Oppm 2.5ppm 1.25ppm 0.63ppm Oppm [II-a] 500ppm 100.0 (97.8) 100.0 (91.6) 100.0 (82.5) 100.0 (30_8) 51.7 (30.8) 2.8 Oppm 97.8 91.6 82.5 30.8 30.8 0 [Table 4] 3rd table potato root nodule nematode Movement inhibition rate (%) π [-a] lOppm 5· Oppm 2_5ppm 1.25ppm 0.63ppm Oppm [II-c] lOOOOppm 100.0 (97.9) 100.0 (91.9) 100.0 (83.1) 100.0 (33_2) 77.1 (33.2) 3.4 Oppm 97.8 91.6 82.5 30.8 30.8 0 [Table 5] Movement inhibition rate (%) of No. 4 sweet potato nodule nematode Π _al lOppm 5. Oppm 2.5ppm 1.25ppm 0.63ppm Oppm [Il-b] 2 5 Oppm 100.0 (92.7) 100.0 (88.5 89.7 (78.8) 67.1 (52.4) 48.2 (449) 12.1 Oppm 91.7 86.9 75.9 45.8 37.3 0 -19- '*1 201124084 [Table 6] Movement inhibition rate of nematode nodules in the fifth table (%) Ϊ́-bl lOppm 5. Oppm 2.5ppm Oppm [Π-c] lOOOppm 97.8 94.0 (93.5) 91.4 (70.9) 3.4 Oppm 100.0 93.3 69.9 0 [Table 7] No. 6 table potato tuberculosis movement inhibition rate (%) il- Bl lOppm 5.Oppm 2.5ppm Oppm [II-c] 500ppm 100.0 (100.0) 100.0 (93.3) 92.1 (69.9) 0 Oppm 100.0 93.3 69.9 0 [Table 8] Table 7: Stem Nodule Nematode Movement Obstruction Rate (%) Π [-bl lOppm 5.Oppm 2.5ppm 1.25ppm 0.63ppm Oppm [Il-b] 250ppm 100.0 (85.5) 94.3 (84.5) 71.1 (49.3) 53.1 (43.4) 37.1 (28.5) 12.1 Oppm 83.5 82.4 42.3 35.6 18.7 0 -20 - 201124084 [Table 9] Movement inhibition rate of No. 8 tube nodule nematode (%) [Ic] lOppm 5.Oppm 2.5ppm 1.25ppm Oppm [II-b] 250ppm 100.0 (96.2) 97.0 (87.4) 70.6 73.5 (48.8) 12.1 Oppm 95.7 85.7 70.3 41.8 0 [Table 10] The hindrance rate of the No. 2 tube nodule nematode (%) fi-cl lOppm 5.Oppm 2.5ppm 1.25ppm Oppm [Π-e] lOOOOppm 100.0 (96.2) 90.1 (87.2) 72.9 49.4 (48.0) 10.6 Oppm 95.7 85.7 70.3 41.8 0 [Table 1 1] The inhibition rate of No. 4 sylvestre root nematode (%) ri-ci lOppm 5. Oppm 2.5ppm 1.25ppm O Ppm [II-c] lOOOOppm 100.0 (96.4) 92.1 (88.1) 79.7 (75.3) 37.6 16.7 Oppm 95.7 85.7 70.3 41.8 0 Γ.;3 -21 - 201124084 [Table 1 2] The 1st table of sweet potato nodule nematode movement hinder Rate (%) η-d lOppm 5.Oppm 2.5ppm 1.25ppm Oppm [Π-a] 500ppm 100.0 (95.9) 100.0 (86.4) 75.9 (71.7) 60.1 (44.5) 4.7 Oppm 95.7 85.7 70.3 41.8 0 [Table 13] 12 Insect blocking rate of Caesarean tuberculosis (%) [Ic] 20ppm lOppm 5.0ppm 1.25ppm Oppm [Il-d] 25 Oppm 100.0 (100.0) 100.0 (96.5) 99.2 (90.5) 58.9 (48.3) 4.1 Oppm 100.0 96.3 90.1 46.1 0 Test Example 2 Water was added to the onion powder at a ratio of 1: 1 Torr and stirred thoroughly. After immersing the 8 cm filter paper in a powder suspension and air-drying, three sheets were placed in an 8 cm culture dish, and 2 ml of a predetermined concentration of the organophosphorus compound and/or the bactericide was added. Each of the culture dishes was inoculated with 50 root female adult worms, and then placed in a constant temperature room of 25 t. After 48 to 72 hours, observe under a stereoscopic microscope, and judge the life and death, and determine the mortality rate. The mortality rate (%) = {1 (number of survival / number of insects)} xl 〇〇 Corby's theory of calculating the mortality rate (%). The experimental 値(%) of the dead worm rate is higher than the theoretical 値(%), and the pest control composition of the present invention has a multiplication effect on the pest control of the root mites-22-201124084 organophosphorus compound: bactericide =1: In the range of 100 to 100: 1 'the experiment showing the mortality rate is higher than the theoretical one. Test Example 3 A mixed loam 3: sand soil 1: humus soil 1 test soil was placed, and 200 g of soil was placed in a plastic container of 300 ml, and a mixed organic phosphorus compound and/or a bactericide was added at a predetermined concentration. Each of the newly hatched chafer larvae was placed in a thermostatic chamber at 25 ° C in the dark for 5 to 10 days, and the soil was disintegrated, and the number of larvae survived was counted to determine the mortality rate. Dead insect rate (%) = {1 - (number of survivors / number of insects)} X100 In addition, the theoretical 値 (%) of the mortality rate can be calculated by the Corby formula. When the mortality rate (%) is higher than the theoretical 値 (%), the pest control composition of the present invention has a synergistic effect on the pest controlling the chafer. In the range of organophosphorus compound··bactericide=1: 1 0 0 0 to 1:6, the experimental 显示 showing the mortality rate is higher than the theoretical 値. Test Example 4 Pour the P A S medium containing the organic phosphorus compound and/or the bactericide to a predetermined concentration in an 8 cm culture dish, which was propagated on other medium.

Rhizoctonia, Pythium, and Fusarium were cultured in a medium containing a hyphal with a 6 mm punch. The mycelial elongation inhibition rate was determined by incubating for 4 to 7 days in a greenhouse at 25 ° C for 4 to 7 days. -23- 201124084 Mycelial elongation inhibition rate (%) = { 1 - (hyphal elongation in drug treatment area / untreated hyphae elongation)} X 1 0 0 In addition, the hyphal elongation inhibition rate can be calculated by Corby formula The theory 値 (%). When the mycelial elongation inhibition rate (%) is higher than the theoretical 値 (°/〇), the pest control composition of the present invention has a synergistic effect on the control of the disease-preventing bacteria. Organophosphorus compound: bactericide = 1: 100 to 10000: 1 The experimental enthalpy showing the mycelial elongation inhibition ratio is higher than the theoretical enthalpy. Test Example 5 3 liters of mixed paddy soil 4: Sand 1 loam was placed in a 1/5 00 0a crucible, and a mixed organophosphorus compound and/or a bactericide was added at a predetermined concentration. Immediately after the addition of the drug, after 500 days and 40 days, 500 cc of the larvae of Meloidogyne incognita was inoculated into the soil, and after thorough mixing, the tomato (variety: strong rice) seedling was transplanted. After 51 days of transplanting, the degree of root nodule of the nematode was investigated (0 to 100% of the birth). The results are shown in Table 13. In addition, for the unified transplant day, the mixed sandy loam and the chemical system are carried out in advance on the date of the calculation of the transplant date. In addition, the theoretical 値 (%) of the degree of root nodulation is calculated by the Corby formula. Root tumor degree (%) If the ratio is lower than the theoretical 値 (%), the pest control composition of the present invention has a synergistic effect on the control of nematodes. The theoretical 値 at this time (% ~ 倂 is shown in the table () of the 13th table. • 24- 201124084 [Table 14] The degree of root nodulation (%) The number of days after the test drug transplantation (Kg ai / Ha) 0 20 40 Ia(3) 30 17 57 II-a(1.5) 100 100 100 Ia(3)+II-a(1.5) 20(30) 10(17) 50(57) II-c(1.5) 100 100 100 Ia(3)+II-c(1.5) 25(30) 10(17) 60 II-d(1.5) 100 100 100 Ia(3)+II-d(1.5) 30 7(17) 53( 57) II-f(1.5) 100 100 100 Ia(3)+II-f(1.5) 20(30) 13(17) 40(57) II-gd.5) 100 100 100 Ia(3)+II- g(1.5) 20(30) 10(17) 50(57) II-i(1.5) 100 100 100 Ia(3 )+II-i(l.5) 17(30) 17 50(57) n-id .5) 100 100 100 Ia(3)+II-j(1.5) 20(30) 10(17) 47(57) II-k(1.5) 100 100 100 Ia(3)+II-k(1.5) 33 10(17) 50(57) No treatment 100 100 100 -25- 201124084 Test Example 6 Soil contaminated with Meloidogye incognita and Fusarium oxysoprum and quantified in 1 / 1 000a plastic mortar, Sowing 7 gherkins (variety: North. After 66 days of sowing, investigate the rate of diseased cucumbers, and the stems of the 2nd to 3rd sections of the cucumber, the catheter The degree of change is based on the five-stage evaluation, and the damage index is calculated based on the evaluation result. This is shown in Table 14. In addition, the test is carried out in a three-line system. In addition, the formula calculates the disease rate and the damage index. If the rate is lower than the theoretical one, the pest control composition of the present invention is related to the multiplication effect of controlling the cucumber cucumber disease. The theory at this time is shown in the table (A): A: The whole plant is dead B: 2/3 or more browning of the catheter C: 1/2 degree browning of the catheter D: browning of 1/3 or less of the catheter E: no browning of the catheter N: number of investigated plants (7 in this test) damage index = { (4a + 3B + 2C+1D/4N)}x100 Phytophthora (mixed with medicinal) seeds and cut off the following results, such as the Corby and the victim system, 値 (%) -26- 201124084 [Table 15 〕 Cucumber vine disease incidence rate test agent (Kg ai / ha) incidence rate (〇 / 〇) victim index Ia (3) 100 82 II-a (3) 100 100 Ia (3) + II-a ( 3) 81(100) 61(82) No treatment 100 100 Test Example 7 (1) Stained by Meloidogye incognita and Fusarium 〇xySOprum The soil and the quantitative Basamid granules (active ingredient ^ -h ) were mixed in 1/1 〇〇〇a plastic ‘ 7 days later and 10 days later, the soil gas was removed. (2) (After the operation, mix the quantified NematorinS granules (active ingredient Ia) in the soil, and after 4 days, sow 7 seeds of cucumber (variety: Beijin). (3) After sowing for 61 days 'Investigate the incidence rate of the cucumber cucumber disease, and calculate the damage index in the same manner as in Test Example 6. And investigate the degree of root nodule of the nematode (0 to 100% of the birth). These results are as shown in the first The table is shown in Table 3. For the comparison, for the case where the contaminated soil is treated with the quantified NematorinS granule (active ingredient la) in (2) without performing the operation (1), And after the operation of (1), in the operation of (2), the same test is carried out without mixing the quantified NematorinS granules (active ingredient Ia) in the soil condition. -27- 201124084 [Table 1 6] Table 15 Multi-disease control test test agent Ginkgo biloba root nodule (Kg ai/ha) Incidence rate (%) Degree of birth index (%) Ia(3) 71 40 5 II-h(294) 79 53 2 Ia (3) +II-h(294) 41 23 0 No treatment 89 60 25 Formulation Example 1 98.3 parts by weight 0.2 parts by weight 1.0 weight 0 parts by weight of 5 parts by weight of 7.7 parts by weight of (1), 1.0 parts by weight of 1.0 parts by weight of 〇. 3 parts by weight of (1) vermiculite fine particles (manufactured by Tokai Kogyo Co., Ltd.) (2) gibberidine ( Fluazinam) (3) Fosthiazate (4) Epoxidized linseed oil. The above-mentioned (2) to (4) heating mixture is blown into the granules. Formulation Example 2 (1) Vermiculite fine particles (made by Tokai Industrial Co., Ltd.) (2) Fluazinam (3) Fosthiazate (4) Epoxidized linseed oil The above (2) to (4) are heated and mixed as a blowing agent for (1). -28 · 201124084 (1) Vermiculite (made by Tokai) (2) Fuaginam (3) Fosthiazate (4) Epoxidized linseed oil 98.3 parts by weight 0-2 parts by weight 1 · 0 parts by weight of 〇. 5 parts by weight, the above (2) to (4) are heated to be mixed as a granule for (1). Formulation Example 2 (1) Fluazinam 20 parts by weight (2) ) Fosthiazate 10 parts by weight (3) Solpol3661S (manufactured by Toho Chemical Co., Ltd.) 1 part by weight (4) Ipuzoll 50 (manufactured by Idemitsu Petrochemical Co., Ltd.) 60 parts by weight The above (1) to (4) were mixed and dissolved into an emulsion. In addition, the contents of the general specification of the present application No. 2004-015667 (applied to the Japanese Patent Office on January 23, 2004), which is the basis of the priority of the present application, is hereby incorporated by reference. Adopter. -29-

Claims (1)

201124084 VII. Patent application scope: 1. A pest control composition characterized by containing thio-sec-butyloxy-ethyl 2-carbonyl-1,3-thiazolidin-3-ylthiophosphonate, And Benomyl is an effective ingredient. 2. The pest control composition according to claim 1, wherein the ratio of the organophosphorus compound to the fungicide is 1:10000 to 10000:1 〇3. A pest control method Characterized by containing thio-sec-butyloxy-ethyl 2 ·carbonyl-1,3-thiazolidin-3-ylthiophosphonate, and Benomyl as an active ingredient acting on harmful organisms . 4. The method for controlling a pest according to claim 3, wherein the organophosphorus compound is allowed to act simultaneously with the fungicide, or the organophosphorus compound is reacted with one of the fungicides, and then Make the other work. 5. The method for controlling a pest according to the third or fourth aspect of the patent application, wherein the ratio of the ratio of the organophosphorus compound to the bactericide is 1: 10,000 to 10,000:1. 6. A method for controlling a pest according to item 3 or 4 of the patent application, wherein the concentration of the active ingredient is 0.1 to 100 〇 ppm. 7. A method of controlling pests in the third or fourth aspect of the patent application, wherein the pest is a harmful organism inhabiting the soil and/or the seed. 8. The method of pest control -30-201124084 of claim 3, wherein the pest is a pest inhabiting the soil and/or seed. 9. For the control of pests in the third or fourth aspect of the patent application, the pest is a plant parasitic nematode. 10. For the method of controlling pests in the third or fourth aspect of the patent application, wherein at least one plant parasitic nematode is selected from the group consisting of the root nodule, the golden nematode 'root rot nematode, the rice heart nematode, Raspberry bud nematodes (Nothotylenchus acris, Strawberry bud nematodes) and Pine wood nemotode (Pine wood nemotode). 11. A method of controlling pests according to claim 3 or 4, wherein the organophosphorus compound is treated with the fungicide in soil and/or seeds. -31 - 201124084 IV. Designation of representative drawings: (1) The representative representative of the case is: None (2) The symbol of the symbol of the representative figure is simple: No. 5. If there is a chemical formula in this case, please disclose the chemical formula that best shows the characteristics of the invention. :no