RU2651290C1 - Substrate for growing fruit seedlings - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention refers to agriculture and can be used during the cultivation of seedlings of fruit plants. Substrate includes the humectant component with microfertilizers from nitrogen, potassium, phosphorus, boron, copper, zinc, manganese, iron and magnesium, according to the invention, the SAP superabsorbent is used as the moisture retaining component, and the substrate further comprises the growth promoter based on indolylacetic acid at the following component ratio, wt%: the growth promoter based on indoleacetic acid – 0.9–1.0 %, nitrogen – 0.15–0.25, phosphorus – 0.45–0.55, potassium – 1.60–2.00, boron – 0.015–0.025, iron – 0.15–0.25, manganese – 0.09–0.11, magnesium – 0.09–0.11, zinc – 0.045–0.55, copper – 0.025–0.035, SAP superabsorbent – the rest.

EFFECT: invention provides for the activation of growth processes and increased fruit yield by means of providing nutrients and full-fledged water accumulation in the root system of the plant.

1 cl, 4 tbl

Description

The invention relates to agriculture and can be used for growing seedlings of fruit plants.

A known substrate for growing vegetative seedlings, including sawdust, adhesive bonding material, which is used bentonite clay containing water, Zn, Al ₂ O ₃ , TiO ₂ , CaO, MgO, MnO, K ₂ 0, Na ₂ O, SO ₃ , ZnO, water pH 7.80, glauconite, having the composition: K ₂ O 220 mg / kg, P ₂ O ₅ 15 mg / kg, nickel 80 mg / kg, manganese 1500 mg / kg, chromium 123 mg / kg, zinc 120 mg / kg, iron 0.30 mg / kg (see RF patent No. 2506740, class A01G 17/02, 2014). The disadvantage of the invention is the lack of moisture accumulation in the root system of the plant.

A known growth promoter based on induloacetic acid (RF patent No. 2430513, class A01N 43/38, 2011) containing a potassium salt of 3-indolylacetic acid, potassium chloride, potassium salt of glycolic acid, potassium dihydrogen phosphate and water and which is environmentally friendly . All compounds included in the described plant growth stimulator are useful for plant development. In addition, the stimulator retains its biological activity for more than three years, but does not provide the accumulation of moisture and nutrients with their subsequent transfer to the plant as necessary.

It is known to use a hydrogel - VLAGOSORB absorbent for the root zones of various plants with the aim of retaining moisture and nutrients with their subsequent transfer to the plant as necessary. The use of VLAGOSORB absorbents helps to create optimal conditions for plant growth, affects the porosity and water permeability of soil and soil mixtures in the root zone of plants. More details: https://attline.ru/p 159079970-gidrogel-dlya-rastenij.html.

A technical solution is also known (RF patent No. 2527215, class C09K 17/00, 2014 - prototype), according to which a substrate is used that includes a water-retaining component in the form of a polyacrylamide hydrogel with micronutrient fertilizers consisting of nitrogen, potassium, phosphorus, boron, copper , zinc, manganese, iron, magnesium. Micronutrient fertilizers are applied mainly by spraying an aqueous solution over the surface of the hydrogel while stirring the mass, followed by drying to avoid clumping of the hydrogel particles.

The disadvantages of the known technical solutions are: the difficulty of applying micronutrient fertilizers, the absence of a growth stimulator for intensifying plant development and the use of a polyacrylamide hydrogel, which, when interacting with water, forms a gel whose density depends on the amount of bound water. With further dilution, the gel can liquefy (dissolve) indefinitely. Therefore, when polyacrylamide is introduced into the soil as a water-retaining component for some time, it works as intended, however, with further water entering the soil, polyacrylamide will gradually be washed out of the root zone of plants. Under the influence of soil carbonates, hydrolysis of polyacrylamide can occur, as a result of which the gel is partially crosslinked and becomes insoluble. But under these conditions, the hydrolysis rate is small, so most of the polyacrylamide will be washed away, as a result of which the duration of the action of polyacrylamide as a water-retaining component will be reduced.

The technical result is to increase the fruit yield by providing nutrients and proper water storage in the root system of the plant.

The technical result is achieved by the fact that in the substrate for growing fruit seedlings, including a moisture-retaining component with micronutrient fertilizers from nitrogen, potassium, phosphorus, boron, copper, zinc, manganese, iron, magnesium, according to the invention, the SAP superabsorbent is used as a water-retaining component, and the substrate is additionally contains a growth promoter based on indolylacetic acid in the following ratio of components, wt.%:

growth stimulator based on indolylacetic acid - 0.9-1.0

nitrogen - 0.15-0.25

phosphorus - 0.45-0.55

potassium - 1.60-2.00

boron - 0.015-0.025

iron - 0.15-0.25

Manganese - 0.09-0.11

magnesium - 0.09-0.11

zinc - 0.045-0.55

copper - 0.025-0.035

superabsorbent SAP - the rest.

New is the fact that the proposed ratio of components allows us to obtain a substrate not only with the optimal composition of macro- and micronutrients for seedlings, but also due to the use of a growth stimulator based on indolylacetic acid, as well as the superabsorbent SAP provides effective water storage with nutrients in the root system of plants , which helps to increase the yield of fruits.

It is significant that the use of the proposed substrate with improved water-physical properties allows you to grow fruiting plants for a long period without applying mineral fertilizers.

The proposed substrate has a high water-containing and buffering ability, high adsorption properties, chemical inertness to phytopathogenic microflora, is not accompanied by salinization during operation and for a long time prevents macro- and microelements from being washed out. When growing seedlings of fruit trees on it, better rooting of cuttings, an increase in growth, and the yield of seedlings by 10-30% are observed in comparison with other substrates.

The choice of the claimed composition as a substrate is due to the following.

Firstly, due to the use of SAP as a superabsorbent component (SAP), this is a completely new type of polymer for agriculture, which can absorb (depending on the model) a huge amount of moisture in just a few minutes (2 minutes are enough for small fractions ) and give moisture to plants almost completely - up to 98% (http://www.bloomingarden.ru/sadovaya-himiya/gidrogel/).

Secondly, the use of a growth stimulator based on indolylacetic acid, which is environmentally friendly, provides, along with effective water accumulation, an intensification of the development of the root system due to all the compounds that make up the plant growth stimulator described. In addition, the stimulator retains its biological activity over three years, which is also necessary for the development of the fetus. The optimal amount of growth promoter is 1.0%. With a smaller amount, there will be insufficient nutrients for the development of the roots of the plant, and with a larger amount, inhibition of the root system can be observed.

Thirdly, the use of micronutrient fertilizers with a certain ratio of micronutrients in combination with a superabsorbent and a growth stimulant depends on the area of use in agriculture, more precisely, on the type of crops (vegetables, grains, legumes, etc.) and soil (acidic, podzolic, clayey, etc.). .), but, as a rule, is not more than 10 ^-1 wt.%. The inventive combination of ratios of trace elements in the substrate is selected for fruit plantations and for soils corresponding to the Northern and Prikubansk fruit zones. Such a low concentration of micronutrients can reduce the amount of fertilizer applied to the soil by several orders of magnitude in the usual way, while the digestibility of micronutrients by all types of fruit crops increases and, as a result, their productivity increases.

Thus, the use of substrate components in the stated ratio allows not only to regulate the growing conditions, creating a favorable water-air regime and the agrochemical properties of the substrate when growing on it fruit stands of various species assortment, but also ensures high survival rate of seedlings.

Since micronutrients and growth stimulants are introduced into the composition of the substrate with a low concentration, the description contains data proving the effectiveness of the claimed substrate.

To prove the effectiveness of the claimed substrate, scientific studies were carried out in the field (North and Prikubanskaya fruit zones), and the results of laboratory experiments in 2013-2016, in accordance with the program and method of variety studies of fruit, berry and nut crops ( The program and methodology of variety studies of fruit, berry and nut-bearing crops / under the editorship of E.N. Sedov, T.P. Ogoltsova. - Eagle: publishing house of the All-Russian Research Institute for Selection of Fruit Crops, 1999. 608 p.).

The repetition in the field experiments was fourfold (30 plants in each variant), and in the laboratory triple. In the field, studies were carried out to assess the survival rate of apple seedlings after planting at a constant place, the biological productivity of the plantings was determined according to the results of agrobiological surveys, the growth of the stem and leaf area, the yield of the plantations and the quality of the fruit.

Field experience diagram:

1. Traditional irrigation technology.

2. Technology using a hydrogel (prototype), 20 g.

3. Technology using the inventive substrate, 20 g.

We studied apple varieties Gala Shniga (autumn variety), Idared (winter variety) grafted on the M-9 stock and planted in the fall of 2012 according to the 3.5 × 0.8 m pattern.

The distribution of precipitation throughout the Krasnodar Territory is extremely uneven. So, in the Northern fruit zone (Kushchevsky district) the amount of precipitation during the study period was 503.5-540.6 mm per year, in the Central subzone of the Prikuban fruit zone - 573.6-751.0 mm., In the Piedmont fruit zone - 476 5-779.3 mm per year. In this case, the balance and moisture of the soil is negative, and the moisture deficit is - 200-260 mm per year. Exceptions are 2012 in the Piedmont Fruit Zone, when 779.3 mm fell during the year, and 371.7 mm during the growing season. However, here too, the deficit of soil moisture in 2012 is 250 mm per year, and in other years - 150-300 mm or more.

As can be seen from the data in table 1, the effect of the use of absorbents was expressed in an increase in the survival rate of seedlings and an increase in growth processes in dynamics.

Table 1. The survival rate (%) of apple seedlings depending on water supply methods (rootstock M9, planting pattern 3.5 × 0.8 m) in 2012

In options 2, 3, where the hydrogel and the inventive substrate were used, regardless of the biological characteristics of the variety and growing conditions, the survival rate increased by 2-4% at the end of the growing season compared to traditional irrigation technology.

Table 2. The nature of the change in the diameter of the stem of apple trees depending on water supply technologies (M9 stock, planting pattern 3.5 × 0.8 m)

The use of the inventive substrate, ceteris paribus, provided 100% survival of apple seedlings of all studied varieties. The difference with the hydrogel was 4-8%.

The results shown in tables 2, 3 show that the diameter of the apple tree trunk in the first year after planting does not change significantly according to the experimental options, and in subsequent years in the Northern fruit zone of the Gala Shniga apple trees in the variants where the inventive substrate was used, the diameter of the stem increases by 10.2-23.0%) (compared with the prototype). This regularity is also preserved in trees of the weak-growing Idared variety, both in the Northern and Prikubansk fruit zones.

Studies have shown that the diameter of the stem, growths and leaf area determine the timing of entry of young trees into fruit bearing. The influence of water supply technologies on the formation of leaf area is given in table 3.

The data in table 3 show that the use of the hydrogel and the inventive substrate significantly increases, compared with traditional technology, the total leaf area on young trees for an average of three years in the Northern fruit zone for the variety Gala Shniga by 18.3-31.7%, for the variety Idared by 30.6-38.6%. In the Prikuban fruit zone, by 22.9-37.7% for the Gala Schniga variety and by 24.5-40.5% for the Idared variety. The presence of a good conductive system to provide moisture and nutrients to the aerial part (root leaves) and a large number of photosynthetic apparatus contributed to an increase in the number of formed fruits (Table 4).

Table 3. Leaf area depending on water supply methods (stock M9, planting pattern 3.5 × 0.8 m)

In the conducted experiments, one-year branched seedlings having 3 to 7 flower buds were used during planting. Therefore, during the autumn (2012) planting, such seedlings of the Gala Shniga variety in 2013 yielded from 3.8 to 6, 8 pcs. fruits, and the trees of the apple tree Idared - from 4.6 pcs. up to 11.4 pcs.

Table 4. Productivity of apple trees depending on water supply (M9 stock, garden planted in autumn 2012)

In 2015, the average number of fruits in the Gala Schniga variety ranged from 16.6 pcs. up to 38.4 pcs., according to the grade Idared - from 22.6 pcs. up to 44.1 pcs Regardless of the variety and fruit zone, it was noted that the use of hydroabsorbents, especially the inventive substrate, over 3 years contributed to an increase in the percentage of useful ovary and the production of Gala Schniga from 3 to 6 kg of high-quality fruits from one tree by 3 years or from 10.7 to 23.2 t / ha. For the Idared variety, from 4.1 to 7.2 kg per tree or 14.6-25.7 t / ha, respectively, which is 2.0-2.2 times more compared to traditional technology.

Thus, it is proved that the use of the claimed substrate during the cultivation of fruit plantings of apple trees (grafted on dwarf rootstocks) optimizes the performance of water supply and increases their productivity.

Claims (3)

A substrate for growing fruit seedlings, including a water-retaining component with micronutrient fertilizers from nitrogen, potassium, phosphorus, boron, copper, zinc, manganese, iron, magnesium, characterized in that SAP is a superabsorbent component and the substrate additionally contains a growth stimulator based on indolylacetic acid in the following ratio of components, wt.%: growth stimulator based indolylacetic acid 0.9-1.0% nitrogen 0.15-0.25 phosphorus 0.45-0.55 potassium 1,60-0,20 boron 0.015-0.025 iron 0.15-0.25 manganese 0.09-0.11 magnesium 0.09-0.11 zinc 0.045-0.55 copper 0.025-0.035 superabsorbent SAP rest