Open Access
Issue
BIO Web Conf.
Volume 17, 2020
International Scientific-Practical Conference “Agriculture and Food Security: Technology, Innovation, Markets, Human Resources” (FIES 2019)
Article Number 00173
Number of page(s) 7
DOI https://doi.org/10.1051/bioconf/20201700173
Published online 28 February 2020
  • A.A. Zhuchenko, Biologization, ecologization, energy saving, the economy of modern sustems of farming, Bull. of the Stavropol AIC, 52, 9–13 (2015) [Google Scholar]
  • V.I. Kiryushin, The problem of farming ecologization in Russia (the Belgorod model), Achiev. of sci. and engineer. in the AIC, 12, 3–9 (2012) [Google Scholar]
  • S.V. Lukin, The experience of biologization of farming in the Belgorod region, Agrochem. Bull., 5, 21–25 (2017) [Google Scholar]
  • V.G. Loshakov, Green manure as a factor of raising soil fertility, biologization and greening of farming, Fertility, 2(101), 26–29 (2018) [Google Scholar]
  • Ya. A. Fedorenko, The formative years and development of organic farming in the Ukraine: a hostorical context, Sci.-theor. and socio-political almanac, 4, 20–23 (Dnepropetrovsk, 2013) [Google Scholar]
  • Dilip Nandwani, ed. Organic farming for sustainable agriculture (Springer, 2016) [CrossRef] [Google Scholar]
  • V. Seufert, Z. Mehrabi, D. Gabriel, T. G. Benton, Current and Potential Contributions of Organic Agriculture to Diversification of the Food Production System Agroecosystem Diversity Reconciling Contemporary Agriculture and Environmental Quality 435–452 (2019) [CrossRef] [Google Scholar]
  • M. Muller-Lindenlauf, Organic agriculture and carbon sequestration, Possibilities and constrains for the consideration of organic agriculture within carbon accounting systems (Natural Resources Management and Environment Department, Food and Agriculture Organization of the United Nations, Rome; Law at University of Gothenburg Vasagatan 1, PO Box 640, SE 405 30 Goteborg, Sweden, 2009) [Google Scholar]
  • H. Kirchmann, G. Thorvaldsson, L. Bergstrom, Fundamentals of organic agriculture past and present, In Organic crop production ambitions and limitations 13–37 (Springer, Netherlands, 2008) [CrossRef] [Google Scholar]
  • A. Pattanapant, G.P. Shivakoti, Opportunities and constraints of organic agriculture in Chiang Mai province, Thailand, Asia-Pacific Develop J., 16(1), 115 (2009) [CrossRef] [Google Scholar]
  • V.I. Kiryushin, Ecological Functions of Landscapes, Eurasian Soil Sci., 51(1), 14–21 (2018) [CrossRef] [Google Scholar]
  • Yu. A. Spiridonov, M.S. Sokolov, A.P. Glinushkin et. al., Adaptive integrated protection of plants (Pechatny gorod, Moscow, 2019) [Google Scholar]
  • V.I. Kiryushin, Theory of adaptive landscaping farming and design of agrolandscapes (KolosS, Moscow, 2011) [Google Scholar]
  • L.V. Ilyina, K.N. Drozhzhin, R.N. Ushakov, Biologization of farming a factor of resource saving and soil fertility conservation, Crop rotation in contemporary farming 166–169 (Publishing house of MAA, Moscow, 2004) [Google Scholar]
  • N.V. Parakhin, Ecological stability and efficiency of plant breeding: theoretical bases and practical experience (Kolos, Moscow, 2002) [Google Scholar]
  • A.B. Nugmanov, Y.V. Tulayev, S.A. Tulkubayeva, S.V. Somova, Developing a system of organic farming technologies to obtain environmentally clean agricultural products (organic food) in the steppe zone of the Kostanai region, OnLine J. of Biolog. Sci., 18(2), 130–137 (2018) [Google Scholar]
  • N. Parrot, T. Marsden, The real Green Revolution: Organic and Agroecological farming in the London, Green peace Environment Trust 1–6 (2002) [Google Scholar]
  • U. Niggli, A. Slabe, O. Schmid, H. Halberg, M. Schluter, Vision for an organic food and farming research agenda to 2025 (IFOAM EU and FiBL, 2008) [Google Scholar]
  • S. Penvern, S. Fernique, A. Cardona, Herz E. Ahrenfeldt et al., Farmers’ management of functional biodiversity goes beyond pest management in organic European apple orchards, Agriculture, Ecosystems & Environment, 284, (2019) [Google Scholar]
  • M.M. Umarov, Associative nitrogen fixation (Moscow State University, Moscow, 1986) [Google Scholar]
  • G.G. Romanov, Symbiotic plants-nitrogen fixers in the flora of the European North-East (SPbGLTU, St. Petersburg, 2014) [Google Scholar]
  • A.L. Toigildin, Comparative yielding capacity and productivity of symbiotic nitrogen fixation of leguminous crops in crop rotation of the forest steppe of the Volga region, Niva Povolzhya, 4(45), 144–151 (2017) [Google Scholar]
  • V.M. Semyonov, B.M. Kogut, Soil organic matter (GEOS, Moscow, 2015) [Google Scholar]
  • S.B. Karunaratne, T.F. Bishop, J.A. Baldock et al., Catchment scale mapping of measureable soil organic carbon fractions, Geoderma, 219, 14–23 (2014) [Google Scholar]
  • The concept of maintaining and improving soil fertility based on biologization of field feed production by natural and economic regions of Russia (Informagrotech, Moscow, 1999) [Google Scholar]
  • A.Kh. Kulikova, A.V. Karpov, I.A. Vandyshev, V.P. Tigin, Agroecological assessment of soil fertility in the Middle Volga region and the concept of its reproduction (Ulyanovsk, 2007) [Google Scholar]
  • V.A. Korchagin, O.I. Goryanin, S.V. Obushchenko, A.P. Chichkin, The concept of reproduction of fertility of black soils in the steppes of the Middle Volga region, Bull. of the Samara Sci. Center of the Russ. Acad. of Sci., 16(5-3), 1081–1085 (2014) [Google Scholar]
  • A.M. Lykov, A.M. Eskov, M.N. Novikov, Organic matter of arable soil in the Non-black soil area (Russian agricultural academy, Moscow, 2004) [Google Scholar]
  • V.G. Sychev, E.N. Efremov, The concept of the program of agrochemical measures till 2020, Innovative solutions to regulating the soil fertility of agricultural land 30 (2011) [Google Scholar]
  • N. Shikula, N. Dolja, The concept of biological function of agriculture for the production of environmentally friendly products, in Ecologicaleconomic problems of the Black Sea region 26–38 (Nikolaev, 1993) [Google Scholar]
  • N. Perez-Consuegra, L. Mirabal, L. C. Jimenez, The role of biological control in the sustainability of the Cuban agri-food system, Elementa-sci. of the Anthropoc., 6(79) (2018) [Google Scholar]
  • Yu.V. Tyutyunov, O.V. Kovalev, L.I. Titova, Spatial Demogenetic Model for Studying Phenomena Observed upon Introduction of the Ragweed Leaf Beetle in the South of Russia, Mathemat. Model. of natural phenom., 8(6), 80–95 (2013) [Google Scholar]
  • N.A. Zelensky, G.M. Zelenskaya, A.Yu. Shurkin, The yielding capacity of sun flower plants under various soil cultivation technologies, Protect. and quarant. of plants, 9, 44–47 (2014) [Google Scholar]
  • V.K. Dridiger, The problems of mastering the “zero” system of farming in the Sravropol region and some areas of their solution, Achievem. of sci. and engineer. in the AIC, 7, 18–19 (2012) [Google Scholar]
  • J.B. Barr, J.M. Desbiolles, J.M. Fielke, M. Ucgul, Development and field evaluation of a high-speed no-till seeding system, Soil and Tillage Research (2019) [Google Scholar]
  • A.L. Toigildin, M.I. Podsevalov, A.V. Karpov, I. A. Toigildina, T.D. Grosheva, The concept of synergism in the farming systems, Res. J. of Pharmaceut., Biolog. and Chemical Sci., 6(4), 227–229 (2015) [Google Scholar]

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