RU2820119C1 - Method of potatoes cultivation according to intensive technology using ultrafine particles in irrigated conditions of steppe zone of orenburg region - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method of potatoes cultivation according to the intensive technology on the irrigated lands of the steppe zone of the Orenburg region, which provides for autumn treatment of soil, application of mineral fertilizers and cutting of ridges, spring planting of potatoes, care of plants, watering and harvesting, in which the pre-planting preparation of tubers for planting was carried out in an electrochemically activated catholyte with pH 8–9 and Eh =-400...-500 mV, stabilized with glycine in amount of 0.01 wt.%, containing ultrafine particles of Mo molybdenum in the emulsion with a hydrodynamic radius of 716 nm and ultrafine particles of silicon oxide SiO₂ with a hydrodynamic radius of 388 nm in a weight ratio of 1:3 with their dosage respectively Mo – 0.045 g/kg, and ultrafine particles of SiO₂ – 0.09 g/kg at pressure of 114*10³ Pa, on an installation with a rotating drum with a drum rotation frequency of 10 rpm, treatment time of 5 minutes and treatment of plant leaves with a suspension of Mo and SiO₂ compounds, in which ultrafine particles of molybdenum and silicon oxide are used, in dosage SiO₂ 6 mg/m²; Mo 2 mg/m², treated with ultrasound.

EFFECT: invention makes it possible to increase crop capacity and quality of potatoes due to creation of more favourable conditions for tuberization and growth of above-ground part of plants.

1 cl, 2 tbl

Description

The invention relates to the field of agriculture.

Background of the Present Invention

The invention relates to the field of agriculture and can be used in improving potato cultivation technology.

Potato (Solanum tuberosum L.) is the main tuber crop that is grown almost all over the world [1].

The planet's population by 2050 will be about 10 billion people, this will lead to an increase in demand for agricultural products by at least 50% compared to 2019 [2]. Climate change is increasing the incidence of abiotic and biotic stress in plants, creating another challenge for agricultural production. Stressful conditions lead to significant economic losses in agricultural production [3]. In the agricultural sector, mineral fertilizers are used to obtain stable yields of agricultural products, but at the same time, their long-term and irregular use causes irreparable damage to the environment and human health. At the present stage, the use of ultrafine particles (UDP) in agricultural production is one of the alternatives to mineral fertilizers [4-6].

Ultrafine particles are one of the effective tools that have yet to be fully used in agronomy. The use of UDC is a new and promising tool that is used in modern agriculture.

Widespread use of UDPs in agriculture will inevitably lead to their dispersion in the environment. It is necessary to understand the mechanism of the impact of particles on soil and vegetation cover, as well as the effect of UDP on food and animal feed. The use of UDP has prospects in practical agriculture from the point of view of stimulating plant growth and increasing productivity, providing plants with microelements [7-8]. The uptake and translocation of UDP has been previously demonstrated under various conditions and for many plant species [9-11].

There is a known method for increasing potato yields, which includes spraying the aerial parts of vegetative potato plants with a solution of the Nano Gro nanopreparation in irrigation water, and the working solution is prepared by dissolving 25 granules of the Nano Gro nanopreparation in 250 liters of irrigation water, and spraying the potato plants is carried out once in stage of budding by fine irrigation at a flow rate of 250 l/ha [12]. The disadvantage of this method is the creation of the effect of “imaginary stress” in plants, which contributes to the natural response activation of the plant’s defense mechanisms at the cellular level.

There is a known method of pre-sowing treatment of spring barley seeds, which are intended for cultivation on gray forest soils. Spring barley seeds of the “Kati” variety are used as seed material, and seed treatment is carried out by soaking them in a suspension containing ultrafine powders of copper and copper oxide with a particle size of 40-60 nm for 30 minutes. The suspension is prepared in a dosage of 0.01 g of copper and copper oxide nanoparticles per hectare seeding rate at the rate of 55 grains per 1 linear meter [13]. The disadvantage of this method is that it is designed for gray forest soils.

There is a known method for pre-sowing treatment of agricultural plant seeds with an aqueous colloidal solution of iron and cobalt nanoparticles in a 1:1 weight ratio, their concentration in the working fluid is 0.006-0.02 g/l, stabilized with 1% polysorbate-20. In this case, the aqueous colloidal solution is subjected to ultrasonic dispersion with a power of 300 W at a frequency of 23.74 kHz 5 times for 5 minutes at an interval of 3 minutes. The disadvantage of this method is the difficulty in preparing a colloidal solution [14].

A means for stimulating the growth of spring wheat has been proposed, which is an aqueous solution of biologically active substances. Iron and molybdenum nanoparticles with a nanoparticle diameter of 90 to 110 nm for iron and from 100 to 120 nm for molybdenum, in a weight ratio of 1:1 and their concentration in the working fluid of 1*10 ^-4 - are used as biologically active substances (BAS). 5*10 ^-4 g/l. The invention provides increased germination energy, germination and increased vitality of plants [15]. The disadvantage of this method is the labor-intensive and complex procedure for preparing the solution.

There is a known method of cultivating potatoes on irrigated lands, which involves carrying out the following operations in the fall: deep autumn plowing with the simultaneous application of organic fertilizers, moldless loosening across the field with the simultaneous application of mineral fertilizers, cutting ridges, spring planting of potatoes, caring for plants, watering and harvesting. Mineral potassium fertilizers are applied once - in the fall. Mineral nitrogen and phosphorus fertilizers are applied twice - in autumn and spring when planting “under a tuber” [16]. The disadvantage of this method is that all soil preparation operations are carried out sequentially one after another, which increases energy costs for obtaining a potato crop and leads to compaction of the soil by heavy machines, especially the subsurface horizon. In addition, during the growing season, when irrigation is carried out, the soil in the ridges becomes compacted, which reduces potato yields.

Another method of cultivating potatoes under irrigated 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% of the lowest moisture capacity (LC) 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 maximum mineral fertilizers N ₁₃₀ P ₁₃₀ K _115, the average potato yield over 3 years increases to 33.0 t/ha [17]. The disadvantage of such methods of cultivating potatoes: low effect when combining 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 NV, the average potato yield decreases by 3.4 t/ha or by 10.3%.

The research examined a natural complex mineral in the form of sand - glauconite, which is used as a fertilizer when 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 in an inaccessible state, improves mineral nutrition and, ultimately, helps to increase potato yields. With a glauconite dose 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 glauconite dose of 40 t/ha and the same level of mineral nutrition – 38.3 t/ha ha [18]. The disadvantage of this method of cultivating potatoes: the use of glauconite together with mineral fertilizers; if only glauconite is present in the soil at a dose of 2 and 40 t/ha (without mineral fertilizers), the potato yield is 29.6 and 33.6 t/ha, respectively, i.e. . Mineral nutrition provides a significant increase in yield; with an increase in the dose of glauconite by 20 times (40:2), the yield increases by 1.135 times.

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

According to literature sources, Molybdenum (Mo) is used by the plant in the biosynthesis of chlorophyll, and is also associated with the absorption of nitrogen, phosphorus and other elements [19], the lack of silicon oxide (SiO ₂ ) inhibits the growth and development of plants. With improved silicon nutrition, the efficiency of photosynthesis and the activity of the root system increase [20].

Asprototypethe method was taken cultivation of potatoes using intensive technology on irrigated lands of the steppe zone of the Southern Urals [21].

The method involves autumn tillage, application of mineral fertilizers and cutting ridges, spring planting of potatoes, plant care, watering and harvesting. Pre-planting preparation of tubers for planting was carried out in an electrochemically activated catholyte with pH 8-9 and Eh = -400÷-500 mV, stabilized with glycine in an amount of 0.01 wt.%, containing in the emulsion ultrafine iron particles 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, of Fe - 16 * 10 ^-4 Mol/l and SiO ₂ NPs - 6 * 10 ^-3 Mol/l under a pressure of 114 * 10 ³ Pa .

The problem to which the claimed invention is aimed is expressed in increasing the yield and marketability of potato plants.

The technical result of the task is to increase the yield and quality of potatoes by creating more favorable conditions for tuberization and growth of the above-ground parts of plants when using UDP Mo and SiO ₂ .

A method of cultivating potatoes using intensive technology on irrigated lands in the steppe zone of the Orenburg region, providing for autumn tillage, the application of mineral fertilizers and cutting ridges, spring planting of potatoes, plant care, watering and harvesting, in which the pre-planting preparation of tubers for planting was carried out in an electrochemically activated catholyte with pH 8-9 and Eh=-400÷-500 mV, stabilized with glycine in an amount of 0.01 wt.%, containing in the emulsion ultrafine particles of molybdenum Mo 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, of Mo - 0.045 g/kg and ultrafine particles of SiO ₂ - 0.09 g/kg under a pressure of 114 * 10 ³ Pa, in an installation with a rotating drum with a drum rotation speed of 10 rpm, treatment time is 5 minutes and the leaves of the plant are treated with a suspension of Mo and SiO ₂ compounds, which uses ultrafine particles of molybdenum and silicon oxide, at a dosage of SiO ₂ 6 mg/m ² ; Mo 2 mg/m ² , treated with ultrasound.

The use of the proposed method for processing potato tubers and leaves allows for more complete use of the genetic potential inherent in the variety through intensive germination of a viable bud within 10-15 days and increasing the plant’s resistance to environmental stress factors (increased air and soil temperatures, etc.) .

Method for preparing solutions for treating tubers

The method was developed on the basis of the Federal Scientific Center for Biological Systems and Agricultural Technologies of the Russian Academy of Sciences (FSBI FSC BST RAS), Orenburg.

For the experiment, we used the potato variety Kuzovok, obtained in the potato breeding laboratory of the 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.

Ultradisperse particles from the Plasmoterm company were obtained by plasma-chemical synthesis.

To disinfect potato tubers, when preparing them for the experiment, they were treated with a 0.01% solution of potassium permanganate.

The stabilizer we offer 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.

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

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

Treatment of tubers is carried out with a stabilized electrochemically activated catholyte with a pH of 8-9 and a redox potential Eh = -400÷-500 mV, stabilized with the amino acid glycine at a concentration of 0.01 wt.%, and containing UDP molybdenum (Mo) with a size of 80 nm and silicon oxide (SiO ₂ ) 25 nm in size in a weight ratio of 1: 3. Concentration in the catholyte UDP SiO ₂ at a dosage of 0.09 g/kg; Mo in a dosage of 0.045 g/kg, under a pressure of 114 * 10 ³ Pa in an installation with a rotating drum with a drum speed of 10 rpm, processing time 5 minutes.

Treatment of plant leaves during the budding phase is carried out with a suspension of Mo and SiO ₂ compounds, at a dosage of SiO ₂ 6 mg/m ² ; Mo 2 mg/m ² , treated with ultrasound.

Dosages of UDC and the design of the experiment on potatoes are presented in Table 1.

Progress of the research . The study was carried out using well-known methods (field experiment methods (Dospehov B.A., 1985), methods of the State Commission for Variety Testing of Agricultural Crops (1985)).

The treated tubers are planted with a potato planter and subsequently grown using existing technology.

To check the achievement of the set goal in our experiment, pre-sowing treatment of tubers, growing, caring for plants and harvesting were carried out on the irrigated plot of the IP "Khomutsky V.I." In autumn, plowing was carried out to a depth of 0.25...0.27 m with the application of fertilizer at a dose of 112 kg of active substance (a.i.) using a milling multi-tiller. In the spring, treatment was carried out with a GRIMME FA 400 cultivator - to a depth of 0.12...0.14 m, with local application of ammophos mineral fertilizers 150 kg a.i. for 1 hectare. The general rate of application of mineral fertilizers was N ₇₅ P ₇₅ K ₁₁₂ kg a.i.

Potatoes were planted with a four-row potato planter GRIMME GL-420 with a row spacing of 0.75 m. The cutting of ridges with a height of 0.23...0.25 m was carried out with a GRIMME ridge former. During the growing season, 5 irrigations were carried out using a BAUER “System 5000” sprinkler with an irrigation rate of 2620 m ³ /ha.

The results of the experiment are presented in Table 2.

Thus, a significant increase in yield above control values (P < 0.05) was recorded for all treatments with ultradispersed particles of molybdenum and silicon oxide. The combined treatment of SiO ₂ (0.09) Mo (0.045) + SiO ₂ (6) Mo (2) was characterized by an increase in yield and marketability of 43.1 t/ha (P < 0.05), 98.5% (P <0.05) versus 33.7 t/ha, 90.2% in the control, which was higher than the control by 21.8 and 8.4%, respectively (Table 2).

The data presented indicate the high efficiency of potato cultivation with combined treatment of SiO ₂ (0.09 g/kg) Mo (0.045 g/kg) + SiO ₂ (6 mg/m ² ) Mo (2 mg/m ² ) tubers and leaves , according to option 3. The method is environmentally friendly and allows you to increase the maximum potential of the variety by improving the technology of potato cultivation, which predetermines an increase in both the quality of the variety and the yield by 20-30%.

Table 1

Option No. Water, ml Types of processing UDP SiO ₂ + Mo potato tubers plants combined 1 (control) 500 0 0 0 2 500 SiO ₂ at a dosage of 0.045 g/kg +
Mo at a dosage of 0.045 g/kg SiO ₂ at a dosage of 3 mg/m ² +
Mo at a dosage of 1 mg/ ^m2 SiO ₂ at a dosage of 0.045 g/kg; Mo at a dosage of 0.045g/kg +
SiO ₂ at a dosage of 3 mg/m ² ; Mo at a dosage of 1 mg/ ^m2 3 500 SiO ₂ at a dosage of 0.09 g/kg +
Mo at a dosage of 0.045 g/kg SiO ₂ at a dosage of 6 mg/m ² +
Mo at a dosage of 2 mg/ ^m2 SiO ₂ at a dosage of 0.09 g/kg; Mo at a dosage of 0.045 g/kg + SiO ₂ at a dosage of 6 mg/ ^m2 ; Mo at a dosage of 2 mg/ ^m2 4 500 SiO ₂ at a dosage of 0.18 g/kg +
Mo at a dosage of 0.045 g/kg SiO ₂ at a dosage of 12 mg/m ² +
Mo at a dosage of 4 mg/ ^m2 SiO ₂ at a dosage of 0.18 g/kg; Mo at a dosage of 0.045 g/kg + SiO ₂ at a dosage of 12 mg/ ^m2 ; Mo at a dosage of 4 mg/ ^m2

Table 2

Qualitative and quantitative indicators on experimental options Name 1 (control) 2 3 4 Productivity, t\ha 33.7±1.2 37.2±1.5* 43.1±1.3* 34.1±2.1* Marketability, % 90.2±1.1* 89.8±1.7* 98.5±1.0* 97.4±1.5* Starch, % 12.5 13.1 13.6 14.2 Dry matter,% 17.8 19.1 18.9 19.3 Reducing sugars, % 0.06 0.07 0.06 0.07 NO ₃ , mg/kg 198 176 138 110

Information sources:

1. Kumar S. Assessment of Plant Extracts and their In Vitro Efficacy against Potato Early Blight Incited by Alternaria Solani / S. Kumar, R. Chandra, L. Behera // J Pure Appl Microbiol. – 2021. – Vol. 15 (3). – p. 1591-1601. – doi:10.22207/JPAM.15.3.55.

2. Anriquez G. Rural population change in developing countries: Lessons for policy making / G. Anriquez, L. Stloukal // ESA Working Papers No. 08–09. Rome, FAO. Pedosphere Available online 7 June 2022.

3. Shabala S. Salt bladders: do they matter / S. Shabala. J. Bose. R. Hedrich // Trends Plant Sci. – 2014. – Vol. 19. – p. 687-691. – doi:10.1016/j.tplants.2014.09.001.

4. Suzuki R.M. Mittler Abiotic and biotic stress combinations / R.M. Suzuki, V. Rivero, E. Shulaev, R. Bloomwald // New Phytol. – 2014. – Vol. 203. – p. 32-43. – doi:10.1111/nph.12797.

5. Kah M. A critical evaluation of nanopesticides and nanofertilizers against their conventional analogues / M. Kah, R.S. Kookana, A. Gogos, T.D. Bucheli // Nat. Nanotechnol. – 2018. – Vol. 13. – p. 677-684. – doi: 10.1038/s41565-018-0131-1.

6. Kah M. Nano-enabled strategies to enhance crop nutrition and protection / M. Kah, N. Tufenkji, J.C. White//Nat. Nanotechnol. – 2019. – Vol. 14 (6). – p. 532-540. – doi:10.1038/s41565-019-0439-5.

7. Kratsch H.A. The ultrastructure of chilling stress / H.A. Kratsch, R.R. Wise // Plant Cell Environ. – 2000. – Vol. 23 (4). – p. 337-350. – doi:10.1046/j.1365-3040.2000.00560.x.

8. Bian S.-W. Aggregation and dissolution of 4 nm ZnO nanoparticles in aqueous environments: influence of pH, ionic strength, size, and adsorption of humic acid / S.-W. Bian, I.A. Mudunkotuwa, T. Rupasinghe, V.H. Grassian // Langmuir. – 2011. – Vol. 27. – pp. 6059-6068. – doi:10.1021/la200570n.

9. Glenn J.B. Interactions of gold nanoparticles with freshwater aquatic macrophytes are size and species dependent: interactions of AuNPs with freshwater aquatic plants / J.B. Glenn, S.A. White, S. J. Klein // Environ. Toxicol. Chem. – 2012. – Vol. 31. – p. 194-201. – doi:10.1002/etc.128.

10. Nath J. Synthesis and characterization of isotopically-labeled silver, copper and zinc oxide nanoparticles for tracing studies in plants / J. Nath, I. Dror, P. Landa, T. Vanek, I. Kaplan-Ashiri, B. Berkowitz //Environ. Pollut. – 2018. – Vol. 242. – p. 1827-1837. – doi:10.1016/j.envpol.2018.07.084.

11. Wojcieszek J. To-do and not-to-do in model studies of the uptake, fate and metabolism of metal-containing nanoparticles in plants / J. Wojcieszek, J. Jiménez-Lamana, L. Ruzik, J. Szpunar, M. Jarosz // Nanomaterials. – 2020. – Vol. 10. – Article 1480. – doi:10.3390/nano10081480.

12. Patent for invention RU No. 2603918 Method for increasing potato yields / A.S. Vasiliev, Z.I. Usanova: published on December 10, 2016, application No. 2015129743 dated July 20, 2015.

13. Patent for invention RU No. 2757791 Method of pre-sowing treatment of spring barley seeds on gray forest soils using copper nanoparticles and copper oxide / T.A. Seregina, Yu.A. Mazhaisky, O.V. Chernikova, M.I. Golubenko, L.E. Ampleeva: published 10/21/2021, application No. 2021106273 dated 03/10/2021.

14. Patent for invention RU No. 2774420 Method of pre-sowing treatment of seeds of agricultural plants / A.A. Gusev, I.A. Vasyukova, O.V. Zakharova, D.V. Kuznetsov, G.I. Churilov: published 06/21/2022, application No. 2021133365 dated 11/17/2021.

15. Patent for invention RU No. 2705272 Means for stimulating the growth of spring wheat / S.V. Lebedev, I.A. Gavrish, L.V. Galaktionova, O.V. Kwan, A.V. Bykov, L.A. Bykova: published on November 6, 2019, application No. 2019119448 dated June 20, 2019.

16. Belt-ridge technology for cultivating and harvesting potatoes (Recommendations). – Moscow, Rosselkhozizdat, 1982. - P. 5-18.

17. Irrigation of potatoes in Western Siberia / I.P. Kruzhilin, V.P. Chasovskikh. – Volgograd: VNIIOZ, 2001. - 37 p.

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

19. Sirieva T.A. The role of mineral nutrition in hydroponic cultivation / T.A. Sirieva, Ya.N. Sirieva // New development impulses: issues of scientific research. – 2020. – No. 1. – P. 129-136.

20. Characterization of Si uptake system and molecular mapping of Si transporter gene in rice / J.F. Ma, N. Mitani, S. Nagao, S. Konishi, K. Tamai, T. Iwashita, M. Yano // Plant Physiol. – 2004. – Vol. 136. – p. 3284-3289.

21. Patent for invention RU No. 2729128 Method of cultivating potatoes using intensive technology on irrigated lands in the steppe zone of the Southern Urals / E.V. Aminova, A.A. Mushinsky, E.A. Sizova, B.G. Rogachev, N.N. Dokina, M.A. Kizaev, D.V. Frolov: published 08/04/2020, application No. 2019120887 dated 07/02/2019.

Claims (1)

A method of cultivating potatoes using intensive technology on irrigated lands in the steppe zone of the Orenburg region, providing for autumn tillage, the application of mineral fertilizers and cutting ridges, spring planting of potatoes, plant care, watering and harvesting, in which the pre-planting preparation of tubers for planting was carried out in an electrochemically activated catholyte with pH 8-9 and Eh=-400÷-500 mV, stabilized with glycine in an amount of 0.01 wt.%, containing in the emulsion ultrafine particles of molybdenum Mo 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, of Mo - 0.045 g/kg and ultrafine particles of SiO ₂ - 0.09 g/kg under a pressure of 114 * 10 ³ Pa, in an installation with a rotating drum with a drum rotation speed of 10 rpm, treatment time is 5 minutes and the leaves of the plant are treated with a suspension of Mo and SiO ₂ compounds, which uses ultrafine particles of molybdenum and silicon oxide, at a dosage of SiO ₂ 6 mg/m ² ; Mo 2 mg/m ² , treated with ultrasound.