Research into Comparative Performance of Different Tillage and Fertilization Systems Applied to Grey Forest Soil of Forest Steppe in Grain Crop Rotation

Kaminskyi, Viktor; Bulgakov, Volodymyr; Tkachenko, Mykola; Kolomiіets, Mykola; Kaminska, Valentina; Ptashnik, Mykhailo; Ivanovs, Semjons; Kiernicki, Zbigniew

doi:10.12911/22998993/155057

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Tytuł artykułu

Research into Comparative Performance of Different Tillage and Fertilization Systems Applied to Grey Forest Soil of Forest Steppe in Grain Crop Rotation

Autorzy

Kaminskyi Viktor , Bulgakov Volodymyr , Tkachenko Mykola , Kolomiіets Mykola , Kaminska Valentina , Ptashnik Mykhailo , Ivanovs Semjons , Kiernicki Zbigniew

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DOI

10.12911/22998993/155057

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Abstrakty

The paper summarises the results of the comprehensive scientific research carried out in the form of a two-factor stationary experiment (5 primary tillage systems × 3 fertilization systems) with rotation (2016–2020) of cereal crops (winter wheat – grain maize – spring barley – soybean) in grey forest fine sand and light loam soil. The effectiveness of the tested agricultural production method has been proven by the amplitudes of the actual cropping capacities: winter wheat – 2.80–5.00 t∙ha^–1; grain maize – 4.16–8.89 t∙ha^–1; spring barley – 1.78–4.45 t∙ha^–1; soybean – 1.02–3.17 t∙ha^–1. The rehabilitation of the physical, agrochemical and biological status of the edatope and the consolidation of the physiological processes in the grain cenoses achieved by the systemic approach to the soil tillage and fertilisation have provided for an increase in the natural biological potential of the plough land by a factor of 1.3–1.8 (from 2.96 to 5.21 t∙ha^–1 of grain units, units for the equivalent measuring of different plant cultivation products). Factographic justification has been provided for the environmental, technological and technical-and-economic feasibility of implementing agronomic technologies based on the adaptive combination of mouldboard and non-mouldboard tillage (to a depth of 6–45 cm) and organic and mineral fertilization system (6.5–7.0 t∙ha^–1 of plant cultivation by-products + N₇₀P₅₈K₆₈). In this case, the effective fertility of an area unit in crop rotation reaches 5.72 t∙ha^–1 in grain units, the production cost of raised grain – 117 €∙t^–1, the earning capacity – 788 € (ha∙year) ^–1, the level of plant cultivation profitability – 139%. In the comparable alternatives of the system-based soil tillage (every-year ploughing, subsurface blade tillage and especially tillage with disk implements), the indices estimated above are significantly lower.

Słowa kluczowe

agrotechnology alternative tillage fertilization productivity soil physics

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 12

Strony

163--178

Opis fizyczny

Bibliogr. 28 poz., rys., tab.

Twórcy

autor

Kaminskyi Viktor

National Science Center, Institute of Agriculture of NAAS of Ukraine, 2-b, Mashynobudivinіkiv Str., Chabany vil., Kyiv-Sviatoshyn Dist., UA 08162, Kyiv Region, Ukraine

autor

Bulgakov Volodymyr

National University of Life and Environmental Sciences of Ukraine, 15, Heroyiv Oborony Str., Kyiv, UA 03041, Ukraine

autor

Tkachenko Mykola

National Science Center, Institute of Agriculture of NAAS of Ukraine, 2-b, Mashynobudivinіkiv Str., Chabany vil., Kyiv-Sviatoshyn Dist., UA 08162, Kyiv Region, Ukraine

autor

Kolomiіets Mykola

National Science Center, Institute of Agriculture of NAAS of Ukraine, 2-b, Mashynobudivinіkiv Str., Chabany vil., Kyiv-Sviatoshyn Dist., UA 08162, Kyiv Region, Ukraine

autor

Kaminska Valentina

National Science Center, Institute of Agriculture of NAAS of Ukraine, 2-b, Mashynobudivinіkiv Str., Chabany vil., Kyiv-Sviatoshyn Dist., UA 08162, Kyiv Region, Ukraine

autor

Ptashnik Mykhailo

National Science Center, Institute of Agriculture of NAAS of Ukraine, 2-b, Mashynobudivinіkiv Str., Chabany vil., Kyiv-Sviatoshyn Dist., UA 08162, Kyiv Region, Ukraine

autor

Ivanovs Semjons

semjons@apollo.lv

Latvia University of Life Sciences and Technologies, Cakstes Blvd. 5, LV 3001 Jelgava, Latvia

https://orcid.org/0000-0002-9072-1340

autor

Kiernicki Zbigniew

Lublin University of Technology, ul. Nadbystrzycka 38 D, 20–618 Lublin, Poland

Bibliografia

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3. Borys, N., Küüt, A. 2016. The influence of basic soil tillage methods and weather conditions on the yield of spring barley in forest-steppe conditions. Agronomy Research, 14(2), 317−326.
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14. Kaminskyi, V., Kolomiiets, L., Bulgakov, V., Olt, J. 2021. An investigation into the state of agricultural lands under water erosion conditions. Agronomy Research, 19(2), 458−471. DOI: 10.15159/AR.21.029
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16. Kolomiiets, L.P., Shevchenko, I.P., Tereshchenko, O.M. 2019. Agroecological effectiveness of soil protection technologies in the system of contour-reclamation organization of land use. Bulletin of Agricultural Science 12, 5–12. (in Ukrainian) DOI: 10.31073/agrovisnyk201912-01
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24. Morgan, R.P.C. 2006. Managing sediment in the landscape: Current practices and future vision. Soil erosion and Sediment Redistribution in River Catchments: Measurement, Modelling and Management, 287–295.
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26. Souza, R., Hartzell, S., Ferraz, A.P.F., Almeida, A.Q., Lima, J.R.S.L., Antonino, A.C.D., Souza, E.S. 2021. Dynamics of soil penetration resistance in water-controlled environments. Soil and Tillage Research, 205, 104768, DOI: 10.1016/j.still.2020.104768
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Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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