RU2048461C1 - Complex microfertilizer - Google Patents

Abstract

FIELD: fertilizers. SUBSTANCE: complex microfertilizer consists of water-soluble inorganic nitrates of rubidium, ammonium, lithium, strontium, magnesium, bismuth (III), mercury (II), lead, thallium (II), cadmium, gallium (III), barium and also sulfates of iron (II), indium (III), cobalt (II), manganese (II), copper (II), tin (II), silver, cesium, ammonium, zinc, nickel and has additionally boric acid, chloroauric acid, potassium chloride, potassium bromide, potassium iodide, potassium arsenate, potassium selenate, potassium tellurate, potassium chromate, sodium fluoride, sodium pyroantimonate, sodium tungstate, calcium chloride, ammonium hydrogen phosphate, ammonium molybdate, ammonium vanadate and water taken at the definite ratio (measured as anhydrous salts, wt.-%). Component ratio mimics the composition of atmospheric aerosol. EFFECT: enhanced effectiveness, decreased doses of conventional organomineral fertilizers. 1 tbl

Description

 The invention relates to complex micronutrient fertilizers (CMF), normalizing and stabilizing the processes of biosynthesis in plants with environmentally friendly means. It can be used mainly for foliar top dressing of all types of plants and presowing treatment of seeds. Fields of application: crop production of open and especially enclosed soil, agricultural chemistry, forestry, research in plant physiology and genetics, production of food microalgae, etc.

The vast majority of chemical trace elements in certain concentrations are necessary for the normal development of plants. Therefore, the effectiveness of mineral fertilizers is higher, the more complete their composition, and the ratio of chemical elements in them, including trace elements, are close to optimal. The ecological purity of such fertilizers is higher, the closer their composition to the natural sources of mineral nutrition of plants. Such a source for almost all biologically active trace elements is global atmospheric aerosols and precipitation of predominantly cosmic origin and cometary nature, which are absorbed by plants directly from the atmosphere by leaves, and by seeds in spring (with melt water) [1] [2]
Known complex compositions of CMU for foliar feeding of plants [3] [4] They increase productivity, plant viability, accelerate ripening, improve the quality of the products. When using CMU [3], the potato yield increases by 40% in cereals by 20-30% carrots by 50% dill by 50-70%, etc. When using the composition of CMU [4] in wheat grains by 2.1% increases the gluten content.

 The composition closest to the proposed one is [4] It includes water-soluble salts of iron, copper, manganese, cobalt, zinc, magnesium, chromium, rubidium, cesium, iodine, bromine, selenium and hydroxyethylidene diphosphate acid as a complexing agent and water.

 Its disadvantages include the absence of many other biologically active trace elements in it: lithium, boron, fluorine, vanadium, nickel, gallium, strontium, molybdenum, silver, indium, tin, tellurium, barium, tungsten, gold, thallium, bismuth, and sufficient quantities of the main macroelements of the plant’s mineral nutrition both from the soil and from the atmosphere: nitrogen, phosphorus, sulfur, chlorine, potassium and calcium. The absence of the former does not provide a complete microelement diet of plants and, accordingly, the maximum efficiency of CMU, and the lack of the latter does not significantly reduce the yield of conventional organomineral fertilizers introduced into the soil without damage to the crop, the excess of which leads to adverse environmental consequences. In addition, in terms of environmental cleanliness, the choice of the complexing agent used in [4] cannot be considered successful, since there are no such compounds among natural sources of trace elements for plants (global atmospheric aerosols).

 The aim of the invention is to increase the efficiency and environmental friendliness of the CMU, taking into account both the composition of the main natural source of biologically active trace elements for plants (cosmic dust of cometary rock), and the physiological needs of plants in individual micro and macro elements of mineral nutrition, as well as the partial replacement of inefficient soil nitrogen sources phosphorus, sulfur, chlorine, potassium and calcium to more effective aerosol.

 For this, the following components are additionally introduced into the CMU [4]: rubidium nitrate, ammonium, lithium, strontium, magnesium, bismuth (III), mercury (II), lead, thallium (III), cadmium, gallium (III) and barium, sulfuric acid iron (II), cobalt (II), manganese (II), copper (II), tin (II), silver, cesium, ammonium, zinc and nickel, as well as boric acid, hydrochloric acid, potassium chloride, potassium bromide, potassium iodide, potassium arsenic-acid, potassium selenic acid, potassium telluric acid, potassium chromic acid, sodium fluoride, sodium pyro-antimony acid, ry tungsten acid, calcium chloride, ammonium phosphate-monobasic acid, molybdenum acid ammonium, ammonium vanadium-acid and water in the following ratio (in terms of anhydrous salt), by weight.

Rubidium nitric acid (0.1-0.2) ˙10 ^-3 ammonium (0.27-2.7) ˙10 ^-1 lithium (0.28-2.7) ˙10 ^-3 strontium (0.44 -4,4) ˙10 ^-2 magnesium (0,19-1,9) ˙10 ^-2 bismuth (III) (0,29-2,9) ˙10 ^-3 mercury (II) (0,78-7 , 8) ˙10 ^-3 lead (0.12-1.2) ˙10 ^-4 thallium (III) (0.62-6.2) ˙10 ^-4 cadmium (0.30-3.0) ˙ 10 ^-3 gallium (III) (0.40-4.0) ˙10 ^-3 barium (0.28-2.8) ˙10 ^-3
Sulphates of iron (II) (0.15-1.5) ˙10 ⁰ cobalt (II) (0.26-2.6) ˙10 ^-3 manganese (II) (0.69-6.9) ˙10 ^{- 1} copper (II) (0.25-2.5) ˙ 10 ^-1 tin (II) (0.45-4.5) ˙10 ^-2 indium (III) (0.70-7.0) ˙10 ^-3 silver (0.65-6.5) ˙10 ^-3 cesium (0.20-2.0) ˙10 ^-3 ammonium (0.70-7.0) ˙10 ^-2 zinc (0.25- 2.5) ˙10 ⁰ nickel (0.58-5.8) ˙10 ^-2 Boric acid (0.17-1.7) ˙10 ^-1 Hydrochloric acid (0.84-8.4) ˙ 10 ^-5 Potassium chloride (0.22-2.2) ˙10 ^-1 Potassium bromide (0.60-6.0) ˙10 ^-1 Potassium iodide (0.98-9.8) ˙10 ^-2 Potassium arsenic - visto-acid (0.12-1.2) ˙10 ^-2 Potassium selenate-acid (0.78-7.8) ˙10 ^-3 Potassium telluric acid (0.16-1.6) ˙ 10 ^{- 2} Potassium chromic acid (0.37-3.7) ˙10 ^-3 Sodium fluoride (0.14-1.4) ˙10 ^-3 Sodium feast o - antimony-acid (0.10-1.0) ˙ 10 ^-3 Sodium tungsten-acid (0.75-7.5) ˙ 10 ^-4 Calcium chloride (0.30-3.0) ˙ 10 ^-1 Ammonium phosphoric acid monosubstituted (0.18-1.8) ˙ 10 ^-1 Ammonium molybdenum acid (0.75-7.5) ˙ 10 ^-3 Ammonium vanadium acid ( , 0.41-4.1) ˙10 ^-3 Water Else
The indicated concentration limits correspond to a decrease in the effect of an increase in productivity by an average of 30% compared with the maximum values within the indicated intervals for each component.

 The proposed composition of the CMU differs from the prototype in its greater environmental purity due to the better approximation of its composition to the natural source of microelements for plants, greater efficiency both in terms of increasing yield, reducing ripening time, improving the quality of the resulting products, and in relation to the less exacting plants to ordinary soil elements nutrition, which can significantly reduce the dose of conventional organomineral fertilizers applied to the soil, or for a certain period not ceive them does little or no damage to the crop and with a corresponding improvement in the overall environmental situation.

 PRI me R. CMU is prepared by sequential dissolution of all these components or their compatible (during long-term storage) mixtures in the required amount of water until each concentration is equal to the geometric mean of the extreme values of the above concentration ranges. The resulting solution is used for presowing treatment of seeds and for foliar feeding of adult plants in the doses indicated below.

The table shows the results obtained for various plants in different regions of the country and at different times for the proposed CMU and prototype relative to the control (without CMU) both on a typical agricultural background and in several cases without applying conventional organic-mineral fertilizers to the soil in the spring of the current and autumn of the previous of the year. The total area in each experiment is not less than 6 hectares, the repetition rate when taking into account the crop is tenfold with an area of not less than 100 m ² in each case. Pre-sowing seed treatment was carried out according to the type of usual “inlay” using conventional water-soluble film-formers and KMU consumption of 0.5 l / kg of seeds. Foliar top dressing of plants was carried out using standard tractor sprayers (boom) with a flow rate of CMU 400 l / ha. Experiments on seed treatment followed by foliar feeding of plants developing from them were not carried out to clearly distinguish between the two effects. It can be expected that both treatments together will produce substantially better results.

 The data presented in the table were obtained after a single exposure to plants in one way or another: seed treatment several days before sowing (planting), foliar top dressing during the budding phase (potato, cotton, cucumbers, flax), tillering (wheat) or closing tops in rows (carrots, beets, cabbage). It can be expected that with more thorough testing of the doses, multiplicity and timing of the proposed CMU, the results can be improved. Thus, the results presented in the table do not reflect the effectiveness of the proposed CMU, which can be achieved in optimal variants of its application.

Claims (1)

 COMPREHENSIVE MICROFERTILIZER based on water-soluble inorganic nitric and sulfate salts and water, characterized in that it contains nitric acid rubidium, ammonium, lithium, strontium, magnesium, bismuth (III), mercury (II), lead, thallium (III) ), cadmium, gallium (III), barium, as sulfate salts, sulfates iron (II), indium (III), cobalt (II), manganese (II), copper (II), tin (II), silver, cesium, ammonium, zinc, nickel and additionally contains boric acid, hydrochloric acid, potassium chloride, bromide, iodide, yshyakovistokisly, selenate, tullurovokisly, chromate, sodium fluoride, pirosurmyanokisly, tungstate, calcium chloride, ammonium dihydrogen phosphate, molybdate, vanadate and water in the following ratios of components (calculated as anhydrous salt), by weight. Nitric acid
rubidium (0.1 0.2) 10 ^{- 3}
ammonium (0.27 2.7) 10 ^{- 1}
lithium (0.28 2.8) 10 ^{- 3}
strontium (0.44 4.4) 10 ^{- 2}
magnesium (0.19 1.9) 10 ^{- 2}
bismuth (III) (0.29 2.9) 10 ^{- 3}
mercury (II) (0.78 7.8) 10 ^{- 3}
lead (0.12 1.2) 10 ^{- 4}
thallium (III) (0,62 6,2) · 10 ^{- 4}
cadmium (0.30 3.0) 10 ^{- 3}
gallium (III) (0.40 4.0) 10 ^{- 3}
barium (0.28 2.8) 10 ^{- 3}
Sulfate
iron (II) 0.15 1.5
cobalt (II) (0.26 2.6) 10 ^{- 3}
Manganese (II) (0.69 6.9) 10 ^{- 1}
copper (II) (0.25 2.5) · 10 ^{- 1}
tin (II) (0.45 4.5) 10 ^{- 2}
indium (III) (0.70 7.0) 10 ^{- 3}
silver (0.65 6.5) 10 ^{- 3}
cesium (0.20 2.0) 10 ^{- 3}
ammonium (0.70 7.0) 10 ^{- 2}
zinc 0.25 2.5
nickel (0.58 5.8) 10 ^{- 2}
Boric acid (0.17 1.7) 10 ^{- 1}
Hydrochloric acid (0.84 8.4) 10 ^{- 5}
Potassium
chloride (0.22 2.2) 10 ^{- 1}
bromide (0.60 6.0) 10 ^{- 1}
iodide (0.98 9.8) 10 ^{- 2}
arsenous (0.12 1.2) 10 ^{- 2}
selenic acid (0.78 7.8) 10 ^{- 3}
telluric acid (0.16 1.6) 10 ^{- 2}
chromic acid (0.37 3.7) 10 ^{- 3}
Sodium
fluoride (0.14 1.4) 10 ^{- 3}
antimicrobial (0.10 1.0) 10 ^{- 3}
tungstate (0.75 7.5) 10 ^{- 4}
Chloride
calcium (0.30 3.0) 10 ^{- 1}
Ammonium
monosubstituted phosphate (0.18 1.8) · 10 ^{- 1}
molybdenum acid (0.75 7.5) 10 ^{- 3}
vanadium (0.41 4.1) 10 ^{- 3}
Water Else

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