AU6339380A - Process for obtaining improved yeilds from plants - Google Patents

Description

PROCESS FOR OBTAINING IMPROVED YIELDS FROM PLANTS

This invention relates to the treatment of plants and compositions for such treatment.

A large number of leguminous plants, such as oilseed rape, peas and beans, are grovn principally for their seed. These seeds are formed in pods vhich, on ripening, split along their longitudinal axes. As a result, the seeds fall onto the ground. Where such crops are mechanically harvested, the problem of seed lost by premature pod splitting can he a serious economic problem. Oilseed rape, vhich is invariably harvested mechanically, has a strongly marked tendency for its pods to split either just before or during harvesting.

In addition to leguminous crops, the seeds or seed-hearing heads or bodies of ornamental plants, cereals (especially barley), grasses grovn for seed production and vegetables being raised for seed all suffer from premature loss of seed before harvesting.

In accordance with the present invention, the loss of seed through premature release or scattering is controlled by the treatment of the crop plant, after seed body formation, with a coating or layering substance that will prevent the detachment of the seed or seed body or will control the splitting of pods or seed-bearing bodies.

The treatment is usually carried out not more than fifteen days before the crop is ready for harvesting, which distinguishes the treatment of this invention from that in prior Applications Numher PCT/GB 80/000l6, European 8032353.0 and UK 8022640, in which coating agents are usually applied at least fifteen days before harvest.

Substances that may be used for this purpose must not affect the subsequent germination of seeds that are destined to be planted. of particular value are a group of pinolene products based on di-l-p-menthene under a variety of trade names including Miller Aide, Miller Gard, Nu-Film P, Nu-Film 17 and Vapor Gard. These products, which contain di-l-p-menthene and certain of its polymers further polymerize to form a film, and such further polymerization may take place or even he induced before application. Other mono terpenes of formula C₁₀H₁₆ , which correspond to tvo isoprene units, can also be used.

Pinolenes are naturally occurring substances and are both expensive and in short supply in relation to possible agricultural needs. It is therefore useful to extend them by using them in combination with other coating agents. Such compounds or mixtures of coating agents (which may be polymerized before application) can shov properties unlike those of their individual components. The mixtures contain from 2 to 10 coating agents, one or more of which is preferably a pinolene compound although mixtures without such compounds may be used.

Apart from the monoterpenes mentioned, the folloving compounds are suitable, though this is not an exhaustive list:- 1. Terpene hydrocarbons of the elementary composition

C₁₅H₂₄, (sesquiterpenes)

2. Terpene hydrocarbons of the elementary composition

C₂₀H₃₂ (diterpenes)

3. Terpene hydrocarbons of the elementary composition C₃₀H₄₈ (triterpenes)

4. Terpenes having 40 carbon atoms (tetraterpenes)

5. Bicyclic and tricyclic monoterpenes and their derivatives (e.g. oxygenated derivatives) such as α and β pinene, d-camphor, d-borneol, d-tanacetone, β-thujone, d- . carene 6. Terpene resins (compounded vith or vithout natural or synthetic rubbers)

7. Gum turpentine

8. Sulphate of turpentine 9. Wood turpentine

10. Pineoils

11. Terpineols

12. Alkyd Resins, Non-oxidizing - e.g. those of the castor oil, coconut oil, hydrogenated castor oil, lauric acid, oil-free, saturated acid and synthetic fatty acid types

13. Alkyd Resins, Oxidizing - e.g. acrylic-resin-modified, dehydrated castor oil types, epoxide-resin-modified, isophthalicacid-based types, linoleic-rich oil type, linseed oil types, linseed oil/dehydrated castor oil types, linseed oil/soya bean oil types, linseed oil/tung oil types, maleic-resin-modified, marine oil types, phenolic-resin-modified, rosin-modified, safflover seed oil types, silicone-resin-raodified, soya bean oil types, soya bean oil/tung oil types, styrenated types, sunfloverseed oil types, tall oil types, tobaccoseed oil types, unmodified types, vinyltoluene-modified and vater-soluble types

14. Benzoguanamine resins

15. Styrene polymers and copolymers, e.g. polystyrene and styrene/maleic anhydride and butadiene/styrene copolymer resins

16. Carbamide resins 17. Copal ester resins

18. Coumarone-indene resins

19. Cresylic resins

20. Epoxy resins - e.g. dehydrated castor oil types, linseed oil types, linseed oil/rosin types, phenolic-resin-modified, soya bean oil types, styrenated types, vinyltoluene-modified, unmodified types, epikote 828 and epikote 1001

21. Epoxide melamine condensates

22. Epoxide phenolic condensates 23. Ester gums 24. Fumaric resins 25. Furan resins

26. Ketone resins

27. Maleic resins 28. Melamine resins - e.g. butylated types, hexamethoxy- methyl types and formaldehyde condensates

29. Metallic rosinates - e.g. calcium or zinc, resinates, zinc/calcium mixtures both rosin or modified rosin

30. Phenolic resins and modified phenolic resins - e.g. phenol/aldehyde resole condensates adducted to rosin or modified rosin, as veil as phenol/formaldehyde resins

31. Phenoxy resins

32. Polybutadiene resins 33. Polybutene resins 34. Polycarbonate resins

35. Polyisobutylene resins

36. Polyester resins - e.g. polyacrylate and polymeth- aciylate ester resins

37. Polysulphide resins 58. Polyurethane resins - e.g. modified types and oilmodified types

39. Polyvinyl acetal resins

40. Polyether resins - e.g. polyvinyl ether resins

41. Polyvinyl formal resins 42. Rosin derivatives - e.g. esters of rosin, copal, rosin acids or rosin modified by hydrogenation, polymerization, isomerization or disproportionation vith glycerol, pentaerytbritol or other polyhydric alcohols

43. Maleic/fumaric condensate resins — e.g. maleic or fumaric acid/anhydride adducts on rosin or modified rosins, their esters with glycerol, pentaerythritol or other polyhydric alcohols

44. Silicone resins and polymers

45. Urea resins — e.g. urea-formaldehyde

46. Xylene-formaldehyde resins 47. Natural gums/resins - e.g. accoroides, arabic, benzoin, copals, damar, elerai, gamboge, karaya, mastic, rosin, sandarac, shellac and tragacanth

48. Acrylic polymers and copolymers - e.g. polyacrylic acid, polyacrylamide, polyacrylonitrile, poly(methyl methacrylate) and poly(ethyl aerylate/butyl acrylate)

49. Cellulose ethers - e.g. hydroxyethyl cellulose and sodium carboxymethyl cellulose

50. Cellulose esters - e.g. methyl cellulose 51. Hydrocarbon resins - e.g. petroleum resins

52. Polyamide resins

53. Rubbers - e.g. natural rubber, butyl rubber, nitrile rubber, polychloroprene, rubber/oil emuline and polyurethane rubber and cyclized rubber resins 54. Vinyl polymers end copolymers other than those already mentioned - e.g. poly(vinyl acetate), poly(vinyl alcohol), poly(vinyl butyral), poly(vinyl pyrrolidone), poly(vinyl acetate/vinyl chloride) and poly(vinyl acetate/acrylate) and

55. Natural drying oils - e.g. linseed oil and tung oil and mixtures of them.

Such substances may be used at rates of from one fluid ounce to ten pints per acre (70 to 14000 ml per hectare) applied in three to one hundred gallons of vater per acre (33.7 to 1120 litres per hectare) of crop. It can be useful to include in the spray preparation a surfactant or vetting agent. Such surfactants include but are not limited to:-

1. alkyl phenolethylene oxide condensate

2. Triton X100

3. Cittovet (trade mark of BASF) 4. alkylated aromatic sodium suphonate

5. amine salts or suphated fatty alcohols and

6. tall oil

The coating or layering substance for checking seed loss hereinbefore described may conveniently be applied mixed with a chemical desiccant, which is a substance that promotes the drying out of the plant to facilitate harvest and/or produces the harvested yield in better condition for storage. Such desiccants include but are not limited to the bipyridilium herbicide diquat (sold under the trade mark Reglone by ICI Ltd) and dinoseb. Diquat has been found especially useful to facilitate the harvesting or oilseed rape and is videly used for this purpose.

The use of the coating or layering substance hereinbefore described for preventing seed loss can result in an increase in the harvested seed yield of oilseed rape while the treatment of this crop with diquat can also result in an increase in the harvested seed yield. These two yield-improving factors act in different ways and, when used together, e.g. when applied either in tank mixtures or separately within seven days of one another, can give an increase in a harvested seed yield that is greater than the sum of the effect of each additive singly.

In another aspect the use of the layering or coating substance hereinbefore described for controlling seed loss can enable a lower rate of desiccant to be applied to an oilseed rape crop or other suitable crop. Because pod splitting is checked the process of desiccation is less demanding, and amounts of desiccant can be reduced by some 30% over what would normally be. recommended.

As is well known, certain weeds in a ripening crop tiat check ripening or interfere with harvesting must be controlled shortly before harvesting. An example of this is the control of sterile brome grass in a cereal crop. Applying a herbicide in conjunction with a composition in accordance with the present invention can be used to con trol such weeds, either by destroying the herbage or by destroying or preventing production of weed seeds. Where the weed is green and alive at the time when the cereal or other crop plant has commenced the ripening process then the crop may be treated with a herbicide, for example glyphosate, that would kill or seriously damage a green (living) crop such as wheat or barley. By its use in conjunction with a coating agwnt in accordance with the present invention, the activity of the herbicide on the weed may be enhanced, while by checking or delaying the entry of the herbicide into the crop the specificity or crop safety of the herbicide is improved. With each additional day of ripening, the crop becomes less susceptible to damage by a herbicide while, since less herbicide is taken into the riper crop, there is a reduction with time in the tendency of the crop to accumulate undesirable residues of the pesticide that could result in the crop being less suitable for human or for animal consumption and its value for seed or malting being reduced since the presence of herbicide in the grain can reduce or slow down germination. The use of a coating agent in accordance with the present invention can make it possible to feed the grain to livestock without further processing and can enhance its value for seed or malting. Delaying the penetration of the herbicide while the crop is ripening before the weed is therefore a desirable objective.

A further value in the use of the coating agent during the ripening period is that, since the loss of seed may be checked, it becomes possible to leave the harvest in the field for a somewhat longer ripening period and thus reduce drying costs.

The tendency of the crop ripening process to be impeded by the coating agent can usefully be overcome by the inclusion of a wetting (surfactant) agent such as 'Agral' (alkylphenol ethylene oxide condensate). When the wetting agent is used in combination with the coating agent and glyphosate, its herbicidal activity can be enhanced by an amount over and above that which is obtainable by the use of either additive considered separately. The coating agent used in accordance with the present invention can be used alone or in conjunction with a fungicide to prevent the development of fungal organisms on the pod or seedbearing body (such as the ear of a cereal plant) and/or the penetration of micro-organisms into the pod to cause loss of yield and/or quality as in the case of "staining" of peas. The control of ear disease in cereals, especially during the ripening process, at which time they are particularly susceptible to cladosporium (sooty mould) disease, may be controlled.

The coating agent may also serve as a physical barrier to the establishment of the fungal organism on the pod or seed-bearing body or seed including the sealing of a pod or seed-bearing structure against the penetration of micro-organisms.

Similarly an insecticide may be incorporated with the coating agent to control pre-harvest insect pests such as cereal aphids and midges. The coating agent, by forming a water-repellent layer over the pod or other, reproductive body, serves to speed its drying and hence to check micro-organism development, which requires moisture in which to flourish.

The coating agent may also be used to bind the fungicide and/or insecticide to the grain of cereal plants before harvesting to preserve them from post-harvest fungal and/or insect attack. This may encompass the use of such agricultural pesticides in a seed crop such that fungal and/or insect attack on the seed folloving planting is reduced.

Examples of fungicides and insecticides that may be used either by incorporation with the coating agent or by use in tank mixture with the coating agent include, but are not limited to, the folloving:- benomyl ethirimol

Bordeaux mixture fenitrothion captafol fentin hydroxide captan malathion carbendazim mancozeb carboxin maneb chlorothalonoil pirimiphos-methyl cyhexatin pyrethrum demephian streptomycin demeton-s-methyl sulphur diazinon thiabendazole dichlorvos triadimephon dicofol thiophanate-methyl dimethirimol tridemorph dimethoate triforine dithiocarbamate fungicide zineb dodine thiram

The foregoing are the trivial names from the Pesticide Index. Herbicides or desiccants may additionally be included in combination with the fungicide and/or insecticide.

A further advantage of a water-repellent coating layer over a pod or seed—bearing body such as a cereal ear is the control or sprouting or premature seed germination. This can he a particular problem in both oilseed rape and cereals. In the case of barley, biochemical changes produced in response to germination (and hence water imbibition by the seed during or after ripening) will lover the malting quality or even render the grain unsuitable for this purpose and hence of lower value.

By acting as a semi-permeable membrane the polymeric coating agents can also prevent re-absorption of moisture after harvest (although not impeding the ripening process). The coating agent may be used to prevent the penetration of an agricultural chemical with which it is applied, for example diquat or paraquat desiccants, through the seed coat of plants such as oilseed rape and soya. Thus, wherever the edible part of the crop is contained within a non-edible structure it is preferable that an applied agricultural chemical be contained on this and not penetrate it and thereby increase the residues or levels of undesirable agricultural chemicals within the seed or other edible portion of the crop.

The coating agent may also be used in combination with a bird repellent. This can be of particular importance in sunflover. In addition to treating pods or seed-bearing bodies, the coating agent, with or without a further agricultural chemical or chemicals, may be used for treating other larger reproductive/storage bodies, such as the ear of maize, which may be treated by dipping or spraying post harvest.

The following experimental data show the effect of various coating agents in the control of pod shatter in oilseed rape. The agent was applied at the time when the pods were turning yellow and pliable, which is also the recommended time for applying the desiccant diquat.

Dried, hand harvested pods vere subjected to a standard treatment of dropping and shaking in bags sufficient to induce 95% shatter in a control sample. Other samples were then similarly treated. In this test therefore a reduction in pod shatter from 95% to 90% represents a 100% increase in unbroken pods.

% Application Rate Pod Shatter (litres per hectare) Control 95

A. Proolxyytteerrppetne Resin (Nitrez) 78 0.7

B. Hydrogenated methyl ester of rosin (100%) (Hercolyn D) 56 0.7 C. Acrylic polymer emulsion (50%)

(VINACRYL 4001) 80 1.4

D. Styrene Acrylic co-polymer emulsion (Vinacryl 7191) 75 1.4

E. Low molecular veight urea formaldehyde-resin (Casco 731) 92 1.4

F. Ester resin in oxital (90%) 90 0.7

G. Di-1-p-menthene 40 0.7 H. Di-1-p-menthene 35 0.7

Except in the case of (H), where application was made in tank mixture with the desiccant glyphosate (Roundup), all applications were made in tank mixture with the desiccant diquat (Reglone) at pints per acre (3.5 litres per hectare) using a spray volume of 50 gallons per acre (560 litres per hectare). Control plants were treated with diquat but received no coating agent. Whole pods taken from the samples described in the foregoing table before induction of shattering were placed in a polythene bag with sufficient water to induce moistening and grovth of fungal moulds. After ten days they were scored from 0 (no growth) to 10 (the level of mould development on the control pods) and the results vere as follows:-

Infestation Score

Control 10

A. Polyterpene Resin (Nitrez) 7 B. Hydroeenated methyl ester of rosin

(100%) (Hercolyn D) 7

G. Di-l-p-menthene (applied with diquat) 5

The foregoing data demonstrate that application of a coating agent can control pod shatter to a marked extent, with concurrent reduction in growth of fungal moulds.

Further experiments were carried out on peas and beans to demonstrate that levels of the pesticide dimethoate (which vas used because it can readily, be assayed accurately and specifically) were diminished by application of a coating agent in accordance with the present invention.

All samples were treated with the standard commercial amounts of Reglone (diquat) + Agral wetting agent viz 3 pints of Reglone plus 6.4 fl oz of Agral per acre (4.2 litres of Reglone plus 450 ml of Agral per hectare) the spray volume being 40 gallons per acre (450 litres per hectare). The amount of di-l-p-menthene was 0.7 litres/ hectare (0.5 pints/acre) and of dimethoate 40% (w/v) was 840 ml per hectare (standard commercial rate). Interval between spraying & harvest ppm Dimethoate (days) in seed

Peas (Little Marvel) (a) Control * 0.009

Dimethoate + Di-l-p- menthene 6 0.037

Dimethoate 6 0.049

Broad Beans (Express) (a) Control * 0.004

Dimethoate + Di-l-p- menthene 6 0.031

Dimethoate 6 0.10

(b) Control * 10 0.006 Dimethoate + Di-l-p- menthene 10 0.11

Dimethoate 10 0.15

All results are corrected for the average recovery

* No dimethoate applied

Claims (10)

1. For use in the prevention or reduction of loss of seeds or seed-bearing bodies from plants, a coating or layering substance that prevents the detachment of the seeds or seed-bearing bodies or controls the splitting of pods or other seed-bearing bodies.

2. A method for the prevention or reduction of loss of seeds or seed-bearing bodies from plants, comprising applying to the plants, not more than fifteen days before the crop is ready for harvesting, a coating or layering substance that prevents the detachment of the seeds or seed-bearing bodies or controls the splitting of pods or other seed-bearing bodies.

3. A method according to claim 2, in which the plants are oilseed rape and the coating substance contains di-l-p-menthene and/or its polymers.

4. A method according to claim 3, in which the di-l-p-menthene is applied together with diquat, which acts as a desiccant.

5. A method according to claim 2, in which a surface-active agent is applied together with the coating substance.

6. Amethod according to claim 2 or claim 5, in which a desiccant is applied together with the coating substance.

7. Di-l-p-menthene for use in the treatment of oilseed rape shortly before harvest to prevent pod splitting.

8. Di-l-p-menthene in combination with diquat, for use in the treatment of oilseed rape shortly before harvest to improve yields and give an improved desiccant action.

9. A method of treating a pod or seed-bearing body of a plant to prevent growth of fungi and micro-organisms and simultaneously prevent premature sprouting of the plant, comprising applying a coating or layering substance as defined in claim 1 to the plant not more than fifteen days before harvest.

10. A method of reducing residue levels in a seed so that the level of harmful residues to animals is reduced and inhibition of germination of the seed can be reduced, comprising applying to a ripening crop carrying the seed a coating agent as defined in claim 1 together with a herbicide.