RU2729128C1 - Method of cultivating potatoes by intensive technology on irrigated lands of steppe zone of southern urals - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture. Method envisages autumn soil treatment, application of mineral fertilizers and cutting of crests, spring potatoes planting, plant care, irrigation and harvesting. Pre-landing preparation of tubers for planting is carried out in electrochemically activated catholyte with pH 8–9 and Eh = −400 ÷ −500 mV, stabilized with glycine in amount of 0.01 wt. %, containing in the emulsion ultrafine iron particles Fe with hydrodynamic radius of 716 nm and ultrafine particles of silicon oxide SiO₂ with hydrodynamic radius of 388 nm in weight ratio of 1:3 at their dosage respectively of Fe - 16 × 10^-4 Mole/l and SiO₂ nanoparticles - 6 × 10^-3 Mole/l under pressure of 114 × 10³ Pa. Treatment is carried out at the apparatus with a rotating drum with a drum rotation frequency of 10 rpm and a treatment time of 5 minutes.

EFFECT: method allows to increase potato yield and quality.

1 cl, 4 tbl

Description

The invention relates to the field of agriculture and can be used to improve the technology of growing potatoes.

Potatoes are one of the strategically important crops for versatile use, both a product for human nutrition and a raw material for the starch and alcohol industry. Russia ranks third in the world for potato production. In countries with developed potato growing - China, USA, Germany, Holland - potato yield reaches 48-60 t / ha. Unfortunately, in Russia, where potatoes are cultivated on an area of more than 3 million hectares, the gross harvest is about 35 million tons, and the yield is about 12 t / ha. Potatoes in Russia: popular, promising, technological and very neglected [1].

The global experience of agriculture shows that the level of crop yields is directly dependent on the amount of fertilizers used. However, from year to year the prices for mineral fertilizers rise, and commodity producers are forced to look for other ways to increase yields. Reducing the use of mineral fertilizers in combination with the use of the latest biotechnological developments contributes not only to an increase in the productivity of agricultural crops, but also allows you to get high-quality ecologically clean agricultural products and reduce environmental pollution [2].

There is a known method of growing potatoes on irrigated lands, which provides for the following operations in autumn: deep winter plowing with simultaneous application of organic fertilizers, moldboard-free loosening across the field with simultaneous application of mineral fertilizers, cutting ridges, spring planting of potatoes, planting, watering and harvesting. Mineral potash fertilizers are applied once - in the fall. Mineral nitrogen and phosphorus fertilizers are applied twice - in autumn and spring when planting "under a tuber" [3].

The disadvantage of this method is that all soil preparation operations are carried out sequentially one after the other, which increases the energy consumption for obtaining a potato crop and leads to soil compaction with heavy machines, especially the subsoil horizon. In addition, during the growing season during irrigation, soil compaction occurs in the ridges, which reduces the yield of potatoes.

Another method of growing potatoes under irrigation conditions is known in the literature, the main components of which are: tillage, application of organic and mineral fertilizers and irrigation of potatoes. For example, with a pre-irrigation soil moisture of 75 ... 80% HB and a dose of organic fertilizers (manure) of 70 t / ha, the average potato yield for 3 years is 29.6 t / ha; with the same dose of manure and a maximum of mineral fertilizers N ₁₃₀ P ₁₃₀ K _{115, the} average potato yield for 3 years increases to 33.0 t / ha [4].

The disadvantage of such methods of potato cultivation: low effect with a combination of three important factors affecting the soil and tubers - high soil moisture, high dose of organic matter, high level of mineral fertilizers; in the absence of mineral fertilizers and maintaining the dose of organic matter (70 t / ha), with the same soil moisture content, the average potato yield decreases by 3.4 t / ha or 10.3%.

The researches studied a natural complex mineral in the form of sand - glauconite, which is used as a fertilizer for growing potatoes. Glauconite contains potassium fertilizer K ₂ O - 8.57%, magnesium fertilizer MgO - 4.31%, other minerals and trace elements. Glauconite improves the agrochemical properties of the soil, absorbs and renders heavy metals inaccessible, improves mineral nutrition and, ultimately, helps to increase the yield of potatoes. With a dose of glauconite application of 2 t / ha in combination with mineral fertilizers N ₆₀ P ₆₀ K ₆₀ , the potato yield is 35.3 t / ha, and with a dose of glauconite of 40 t / ha and the same level of mineral nutrition - 38.3 t / ha [5].

The disadvantage of this method of potato cultivation: the use of glauconite together with mineral fertilizers, in the presence of only glauconite in the soil at a dose of 2 and 40 t / ha (without mineral fertilizers), the potato yield is, respectively, 29.6 and 33.6 t / ha, i.e. ... a significant increase in yield is provided by mineral nutrition; with an increase in the dose of glauconite 20 times (40: 2), the yield increases 1.135 times.

From this study, it follows that it is necessary to introduce highly effective nanotechnologies that increase yields and resistance to adverse natural factors.

Over the past decades, in many countries of the world, nanomaterials and nanotechnologies have found application in almost all areas of agriculture [6, 7].

Nanoparticles of metals, including iron, are especially actively studied. It is noted that for the manifestation of biological activity, metal nanoparticles must be processed under certain conditions [8].

The known method of pre-planting preparation of potato tubers includes treatment with a suspension of iron compounds, which uses nanoparticles of iron oxyhydroxide, treated with ultrasound [9].

This method is highly effective, but differs in the complexity of implementation and the high cost of the resulting product.

Science and practice have accumulated significant experience in the influence of highly dispersed metal particles on the growth and development of plants. The interaction of metal nanoparticles with plants is accompanied by their incorporation into membranes, penetration into cells and cellular organelles, interaction with nucleic acids and proteins, which can significantly change the functions of various biological structures [10, 11].

Using the achievements of application nanotechnology (NP) when treating potato tubers together in a mixture with catholyte, as a doping to overcome negative effects [12], it is possible to significantly increase their energy of germination, germination and growth [13].

It is known that the lack of silicon inhibits the growth and development of plants. The conclusions of the world's leading scientists put forward the properties of silicon in the first place [14]. With the improvement of silicon nutrition, the efficiency of photosynthesis and the activity of the root system increase [15].

The stimulating effect of iron nanoparticles on increasing the energy of germination and germination of seeds is also known, confirmed by the results of studies [16, 17, 18].

Analysis of available information sources did not reveal the use of ultradispersed particles (hereinafter UDF) of iron Fe of optimal dosage [19, 20] and UDF of silicon oxide SiO ₂ in a mixture with catholyte during processing under pressure, as a way to increase potato yield. At the same time, the task was to establish the processing time at the optimal dosage of UDP SiO ₂ in combination with the optimal dosage for UDP Fe in the catholyte solution.

Thus, the claimed technical solution corresponds to the patentability "novelty".

The aim of the invention is more intensive germination, accelerated plant development and increased potato yield. This goal is achieved by the fact that, according to the proposed method, tubers are processed before planting under a pressure of 114 * 10 ³ Pa in an ECA emulsion of a catholyte with UF Fe and SiO ₂ , with catholyte indicators pH 8-9 and a redox potential Eh = -400 ... -500 mV , stabilized with glycine in an amount of 0.01 wt. % on a unit with a rotating drum with a frequency of 10 rpm for 5 min.

The characteristics of ultradispersive particles (UDP) are presented in table. 1.

The method allows to increase the yield and quality of potatoes due to the creation of more favorable conditions for tuberization when using UFC Fe and SiO ₂ .

The use of the proposed method of electrochemical activation of potato tubers makes it possible to make fuller use of the genetic potential inherent in the variety by intensive germination of a viable bud for 10-15 days.

As a prototype and control in the experiment, the known method of potato cultivation on irrigated lands was used [21].

For the experiment, the potato variety Izil was used, selected from botanical seeds obtained from the crossing of the Kondor and Fresko varieties in the potato selection laboratory South Ural Research Institute of Horticulture and Potato Growing - a branch of the Ural Federal Agrarian Research Center of the Ural Branch of the Russian Academy of Sciences ...

The mode of treatment of potato tubers is presented in table 2.

To disinfect potato tubers during their preparation for the experiment, they were treated with a 0.01% solution of potassium permanganate.

Our proposed stabilizer demonstrates stable antimicrobial and antifungal activity, long-term preservation of the redox potential of the cathode aqueous solution and is an amino acid from the group of polar (hydrophilic) uncharged amino acids in an amount of at least 0.01 wt. %, in our experiment glycine [22].

An aqueous solution of catholyte with a pH of 8-9 and a redox potential Eh = -400 ... -500 mV was obtained in the experiment by electrolysis of tap water using a bioelectroactivator "Espero-1".

The initial data of the tap water used in the experiment corresponded to the requirements of SanPin 2.1.4.1074-01.

The treated tubers are planted with a potato planter and subsequently grown according to the existing technology.

To check the achievement of this goal in our experiment, the pre-sowing treatment of tubers, cultivation, care of plants and harvesting were carried out on an irrigated plot of LLC "Agrofirma Promyshlennaya". In autumn, plowing was carried out to a depth of 0.25 ... 0.27 m with fertilization at a dose of 112 kg. etc. milling multitiller. In the spring, the cultivator GRIMME FA 400 was processed to a depth of 0.12 ... 0.14 m, with local application of 150 kg of ammophos fertilizers. etc. per 1 hectare. The total application rate of mineral fertilizers was N ₇₅ P ₇₅ K ₁₁₂ kg. etc.

The potatoes were planted with a four-row potato planter GRIMME GL-420 with a row spacing of 0.75 m. Ridges with a height of 0.23 ... 0.25 m were cut with a GRIMME ridge former. During the growing season, 5 irrigations were carried out with a BAUER sprinkler "system 5000" with an irrigation rate of 2750 m ³ / ha.

The experimental results are presented in tables 3 and 4.

Thus, a significant increase in the number of stems per plant above the control values (P <0.05) was recorded during all treatments with ultradispersed iron and silicon oxide under a pressure of 855 mm Hg. For a time range of 5-10 min. an increase in stem weight was 916 ± 19.1 - 1028 ± 14.9 g versus 785 ± 12.3 g in the control (P <0.05) (Table 4). At the same time, a separate aspect of the obtained result was the largest number of tubers per 1 plant in the control variant - 14 ± 1.2 pcs. At the same time, the proposed pre-planting method for treating potato tubers with ECA catholyte under a pressure of 855 mm Hg. within 5 minutes according to option I (Table 2) showed that the mass of tubers on the 70th day after planting exceeded the control by 1.5 times, and options I and III by 15% and 54%, respectively (Table 4).

The given data indicate the high efficiency of cultivation of the method of potatoes under pressure for 5 minutes according to the first option. The method is environmentally friendly and allows you to increase the maximum potential of the variety by improving the technology of cultivation of potatoes, which predetermines the increase in both the quality of the variety and the yield by 30-40%.

1. [Electronic resource] // Daily Agrarian Review. URL: http://agroobzor.ru/rast/a-126.html (date of treatment 01/27/2015).

2. Sukov A.A., Chukhina O.V. Development of a fertilization system for agricultural crops in the northern part of European Russia. - Vologda - Dairy: ITsVGMKHA, 2013 .-- 152 p.

3. Belt-ridge technology of cultivation and harvesting of potatoes. Recommendations, 1982. - S. 5-18.

4. Kruzhilin I.P. and other Irrigation of potatoes in Western Siberia. - Volgograd: VNIIOZ, 2001 .-- 37 p.

5. Vasiliev A.A. Glauconite is an effective natural mineral fertilizer for potatoes // magazine "Agrarian Bulletin of the Urals" 2009. - No. 6 (60) - pp. 35-37.

6. Liang YC, Chen Q, Liu Q, Zhang WH, Ding RX Exogenous silicon (Si) increases antioxidant enzyme activity and reduces lipid peroxidation in roots of salt-stressed barely (Hordeum vulgare L.). J of Plant Physiol. 2003.160: 1157-64.

7. Zhu JK (2003) Regulation homeostasis under salt steress. Current Opinion in Plant Biology 6 (5): 141-145.

8. Kovalenko L.V., Folmanis G.E. Biologically active iron nanopowders. Moscow: Nauka, 2006 .-- 126 p.

9. RF patent No. 2545667. Published on April 10th, 2015. Bul. No. 10.

10. Kefeli V.I. Plant growth and natural regulators. Plant physiology. T. 25. Issue. 5.Moscow, Science, 1978.

11. Potato growing: history of development and results of scientific research on potato culture: collection of articles. scientific. tr. FGBNU VNIIKH, ed. S.V. Zhevory. M., 2015 .-- 449 p.

12. Patent RU No. 2234945. Published on August 27, 2004. Bul. No. 14.

13. Vinogradova D.L., Malyshev R.A., Folmanis G.E. Economic aspects of the application of nanotechnology in agriculture / Under. total ed. G.V. Pavlova - M .: Research Center for the Problems of the Qualities of Specialist Training. 2005 .-- S. 8-34.

14. Ma, J.F. et al. (2004) Characterization of Si uptake system and molecular mapping of Si transporter gene in rice. Plant Physiol. 136, 3284-3289.

15. Wang S.Y., Galletta G.J. Foliar application of potassium silicate induces metabolic changes in strawberry plants. Journal of Plant Nutrition. Vol. 21, Iss. 1.1998.

16. Patent RU No. 2635103. Published on November 09, 2017. Bul. No. 31.

17. Patent RU No. 2623471. Published on June 26th, 2017. Bul. No. 18.

18. Patent RU No. 2627556. Published on June 8th. 2017. Bul. No. 22.

19. Heather A. Currie, Carole C. Perry. Silica in plants: Biological, biochemical and chemical studies // Ann. Bot. 2007. December. 100 (7). P. 1383-1389.

20. Matychenkov V.B., Bocharnikova E.A., Kosobryukhov A.A., Bil K.Ya. On mobile forms of silicon in plants // DAN RAN. 2008. T. 418. No. 2. S. 279-281.

21. Patent RU No. 2354095. Method of potato cultivation on irrigated lands / I.P. Kruzhilin, V.V. Melikov et al. Published on May 10, 2009. Bul. No. 13. - prototype.

Claims (1)

A method of cultivating potatoes using intensive technology on irrigated lands of the steppe zone of the Southern Urals, providing for autumn tillage, the introduction of mineral fertilizers and cutting of ridges, spring planting of potatoes, planting, watering and harvesting, in which the pre-planting preparation of tubers for planting was carried out in electrochemically activated catholyte with pH 8-9 and Eh = -400 ÷ -500 mV, stabilized by glycine in an amount of 0.01 wt%, containing in the emulsion ultrafine particles of iron Fe with a hydrodynamic radius of 716 nm and ultrafine particles of silicon oxide SiO ₂ with a hydrodynamic radius of 388 nm in a weight ratio of 1: 3 with their dosage, respectively Fe - 16 * 10 ^-4 mol / l and NP SiO ₂ - 6 * 10 ^-3 mol / l under a pressure of 114 * 10 ³ Pa, on a unit with a rotating drum with a drum rotation frequency 10 rpm, processing time 5 minutes.