Soil-water-security Systems of Agriculture and Adaptation to Changes of Climate

Source:
By:Svetlana Vasilievna Budnik

DOI: https://doi.org/10.30564/hsme.v3i1.3172

Abstract:

In article the expediency of application of methods of protection soils from erosion and in general principles of the antierosion organization of territory of land tenure for adaptation of territories to changes of a climate is considered. The expediency of updating of these methods in connection with new results of supervision for runoff on slopes and the new purposes of their application is shown. In particular, it is shown, that antierosion constructions need to be placed above a place of concentration of a runoff, instead of on it as the probability of destruction of a construction in this place is great. Application the soil-water-security systems of agriculture provides regulation of a microclimate of territory (reduction of warming up of a surface), allows to lower peak of a high water from downpours, translating a part of a superficial runoff in intrasoil and underground and to these to prevent losses from them including loss of a fertile layer of soils, saturation by a moisture of a zone of aeration favorably influences development of forest vegetation and agricultural crops.

References:

[1]Agafonov, B.P. (1996), “Development of slopes in a view of the concept faltering denudations and accumulations”. Geomorphology, 1, 3-11. (in russion). [2]Befani, A.N. (1949), “Bases of the theory of a storm runoff.” Part 1. Works OGMI, 4, 39-175. (in russion). [3]Befani, A.N. (1986), “Mathematical modelling of process of storm erosion slope”. Meteorology, climatology and hydrology, 22, 79-87. (in russion). [4]BULLETIN WMO, (2012), 61 (1), 40. [5]BULLETIN WMO, (2017), 66 (2), 60. [6]BULLETIN WMO, (2020), 69 (1), 76. [7]Belolipskij, V.A. etc. (1990), “Methodical instructions by definition of a potential runoff with elementary catchments and to designing soils of water-security actions at contour-meliorative agriculture”. Lugansk: UNIIZPE, 35 p. (in russion). [8]Budnik, S.V. (2001), “The development of scarps in erosion rills on slopes”. Eurasian Soil Science, 34, 9, 1024-1028. [9]Budnik, S.V. (2002), “Some principles of accommodation of antierosion constructions on slopes in view of their spatial stability”. Agrochemistry і soil science. 63, 103-110. (in russion). [10]Budnik, S.V. (2007), “Storm a runoff with slopes”. Zhitomir. 184. (in russion). [11]Budnik, S.V. (2010), “Thawed a runoff with slopes”. Zhitomir, 342. (in russion). [12]Budnik, S.V. (2020), “Change of Fertility Soils on a Background of Changes of a Climate. Advances in Earth and Environmental Science”, 1.1, 1-4. doi. org/10.47485/2766-2624.1005. [13]Gerasimenko, V.P., Kumani, M.V. (2000), “Recommendation on regulation of soil-hydrological processes on arable agriculture”. Kursk, 84. (in russion). [14]De la Casa, A. C., Ovando, G. G., Nasello, O. B. (2018), “Changes in the Intensity and Variability of Precipitation in the Central Region of Argentina between 1960 and 2012”. Climate, 6. 66, 1-23. DOI: 10.3390/cli6030066. [15]Demidov, V.N. (1973), “One-dimensional hydrodynamical models sloping a runoff”. Meteorology and a hydrology, 11, 69-76. (in russion). [16] Eriyagama, N., Smakhtin, V. Gamage N. (2009), “Mapping Drought Patterns and Impacts: a Global Perspective”. IWMI Research Report No. 133. Colombo, International Water Management Institute, http://www.iwmi.cgiar.org/Publications/IWMI_Research_Reports/PDF/PUB133/RR133.pdf. [17] Fatou, Bojang, Seydou, Traore, Adama, Togola1, Yacouba, Diallo. (2020), “Farmers Perceptions about Climate Change, Management Practice and Their On-Farm Adoption Strategies at Rice Fields in Sapu and Kuntaur of the Gambia, West Africa”. American Journal of Climate Change, 9, 1-10. [18] Fazel-Rastgar, F. (2020), “Seasonal Analysis of Atmospheric Changes in Hudson Bay during 1998- 2018”. American Journal of Climate Change, 9, 100- 122. https://doi.org/10.4236/ajcc.2020.92008. [19] Foster, G.R. (1982), “Modeling the erosion process”. Jn: C.T.Haan(ed) Hydrologic Modeling of Small Watershed.-ASAE Monography. 5. St.Joseph. M.J. 297- 380. [20] Gerasimenko, V.P. (1993), “Estimation of a spring superficial runoff from arable lands”. Soil science, 5, 84-91. (in russion). [21] Gopchenko, E.D. (1975), “About a reduction of the maximal modules of a rain drain on the area”. Meteorology and a hydrology, 2:, 66-71. (in russion). [22] Horton, R.E. (1935), “Surface runoff phenomena. Part I - Analysis of the hydrograph”/ Horton Hydr. Lab. Pub. 101. Edwards Bros. Am. Arbor, 73. [23] Horton, R.E. (1945), “Erosional development of streams and their drainage basins: hydrophysical approach to quantitative morphology”. Bulletin of the Geological Society of America 56. 2 75-3 70. [24] Ivanenko, A.G. (1983), “Calculation of a hydrographer of a rain runoff in view of dynamics of speed lag-time and sloping a runoff”. Works Ukr. NIGMI, 194, 32-41. (in russion). [25] The instruction by definition of settlement hydrological characteristics at designing antierosion actions in European territory SSSR. (1979), Leningrad: Gidrometeoizdat, 62. (in russion). [26] IPCC. (2001), “Climate Change 2001”: Synthesis Report. A Contribution of Working Groups I, II, and III to the Third Assessment Report of the Intergovernmental Panel on Climate Change [Watson, R.T. and the Core Writing Team (eds.)]. Cambridge University Press, Cambridge, United Kingdom, and New York, NY. USA. 398. [27] “Land husbandry – components and strategy”. (1996), By Eric Roose. 70 FAO soils bulletin. Rome, 302. [28] Lisetskij F.N., Pavljuk J.V., Kirilenko Z.A., Pichura V.I. (2014), “Catchments the organization of wildlife management for the decision hydroecological problems”. Meteorology and a hydrology, 8, 66-75. (in russion). [29] Kevin, E. (2011), “Trenberth Changes in precipitation with climate change”. “Climate research”, 47, 123-138. DOI: 10.3354/cr00953. [30] Krasnov, S.F. (1987), “Definition of loss at watering on furrows”. Agriculture, 5, 54-57. (in russion). [31] Medvedev, V.V., Bulygin, S.JU. (1989), “Designing cultural agrolandscape”. Agriculture, 2, 45-50. (in russion). [32] Mirtshulava, TS.E. (1988), “Bas of physics and mechanics of erosion channel”. Leningrad: Gidrometeoizdat, 303. (in russion). [33] Svetlichnyj, A.A. (1999), “Printsipy of perfection of empirical models of loss of soils”. Soil science. 8, 1015-1023. (in russion). [34] Sokolov, V.T. (1973), “Gydrodynamical and the hydraulic equations describing sloping rain stream in view of infiltrations”. Water resources, 2, 95-110. (in russion). [35] Suhanovsky, JU.P. (1988), “Hydromechanical model of rain erosion soils”. Reports VASXNIL. 9, 43-45. (in russion). [36] Shvebs, G.I., Svetlichnyj, A.A. (2001), “Geomorphological of a condition of superficial loss of soils.” Ukrainian geographical journal, 4, 34-40. (in russion). [37] Westra, S., Fowler, H. J., Evans, J. P., Alexander, L. V., Berg, P., Johnson, F., Kendon, E. J., Lenderink, G., Roberts, N. M., (2014), “Future changes to the intensity and frequency of shortduration extreme rainfall,” Rev. Geophys., 52, 522-555. DOI: 10.1002/2014RG000464. [38] World Meteorological Organization (WMO), (2013), United Nations Convention to Combat Desertification (UNCCD) and Food and Agriculture Organization of the United Nations (FAO) High Level Meeting on National Drought Policy, Geneva, 11–15 March Policy Document: National Drought Management Policy. Geneva, http://www.wmo.int/pages/ prog/wcp/drought/hmndp/documents/PolicyDocumentRev_12-2013_En.pdf. [39] World Meteorological Organization (WMO) and Global Water Partnership (GWP) (2016), “Handbookof Drought Indicators and Indices” (M. Svoboda and B.A. Fuchs). Integrated Drought ManagementProgramme (IDMP), Integrated Drought Management Tools and Guidelines Series 2. Geneva, 60.