Development of a criteria­based approach to agroecological assessment of slope agrolandscapes

Authors

DOI:

https://doi.org/10.15587/1729-4061.2018.148623

Keywords:

sloping agrolandscape, erosion resistance, soil washout, microstream, water catchment, microwatercourse resistance

Abstract

For the forecast and management of erosion processes in order to protect the environment, information is needed on the state of its components and impact factors as well as the results of this impact. The existing methods for assessing the catchment area are mainly descriptive and cannot be used in mathematical prediction problems. The most accurate formulation of the problem of quantitative assessment of the catchment area is carried out during hydrological calculations. It seems expedient to develop theoretical prerequisites for agroecological assessment of slope agrolandscapes on the stability of a network of temporary watercourses by using the Lokhtin criterion.

Slope agrolandscapes are erosive dangerous objects. The existence of a continuously changing system of microstreams generated by precipitation on slopes greatly complicates the situation. Criteria are proposed to determine the main trends in the development of watercourses of river systems by washing away or depositing soil. Conclusions about the catchment area as a whole can be obtained by examining a certain area of a microstream flow for a long time and comparing field observations with laboratory experiments. To determine the sustainability of a watercourse, a theoretically reasonable value has been proposed, which allows quantifying the network of temporary streams. When conducting research, data on the catchment area of the Tsivil river (Chuvash Republic, Russia) from 1950 to 2010 were used.

A quantitative assessment of the erosion resistance of the microstream system was carried out both for periods of snowmelt and for rains, conventionally divided into summer and autumn. The theoretical background considered is confirmed by the data of long­term observations on the Great Tsivil river for sixty years. The dependences obtained make it possible to compile an adequate forecast of the direction of evolution of the catchment area in relation to the processes of soil deposition or its washing out. The criteria developed are applicable both to a specific catchment area of microstreams and to the catchment area of a river system as a whole

Author Biographies

Victor Alekseev, Cheboksary Cooperative Institute Gor’kogo ave., 24, Cheboksary, Russia, 428025

Doctor of Technical Sciences, Professor

Department of Information Technologies and Mathematics

Vladimir Maksimov, Ural Polytechnic College – MCK, branch in the city of Nyagan Sibirskaya str., 5/4, Nyagan', Russia, 628187

PhD

Sergey Chuchkalov, Chuvash State University named after I. N. Ulyanov Moskovskij ave., 15, Cheboksary, Russia, 428015

Department of General Physics

Vladimir Medvedev, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of Transport and Technological Machines and Complexes

Petr Mishin, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of Transport and Technological Machines and Complexes

Yurij Kazakov, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Associate Professor

Department of Transport and Technological Machines and Complexes

Nadezhda Kondratieva, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of mechanization, electrification and automation of agricultural production

Petr Lekomtsev, Izhevsk State Agricultural Academy Studencheskaya str., 11, Izhevsk, Russia, 426069

Doctor of Technical Sciences, Professor

Department of Power Engineering and Electrical

Gubeydulla Yunusov, Mari State University Lenina sq., 1, Yoshkar-Ola, Russia, 424000

Doctor of Technical Sciences, Professor

Department of Mechanization of Production and Processing of Agricultural Products

Nikolaj Obolensky, Nizhny Novgorod State Institute of Engineering and Economics Oktyabrskaya str., 22a, Knyaginino, Nizhegorodskaya region, Russia, 606340

Doctor of Technical Sciences, Professor

Department of Technical Service

References

  1. Walling, D. (2009). The impact of global change on erosion and sediment transport by rivers: current progress and future challenges. The United Nations World Water Development Report 3: Water in a Changing World. Paris: UNESCO, 26.
  2. Graiss, W., Krautzer, B. (2011). Soil Erosion and Surface Runoff on Slopes in Mountain Environment Depending on Application Technique and Seed Mixture – A Case-Study. Soil Erosion Studies, 193–212. doi: https://doi.org/10.5772/25124
  3. Rodrigo-Comino, J., Brings, C., Iserloh, T., Casper, M. C., Seeger, M., Senciales, J. M. et. al. (2017). Temporal changes in soil water erosion on sloping vineyards in the Ruwer- Mosel Valley. The impact of age and plantation works in young and old vines. Journal of Hydrology and Hydromechanics, 65 (4), 402–409. doi: https://doi.org/10.1515/johh-2017-0022
  4. Sensoy, H., Kara, O. (2014). Slope shape effect on runoff and soil erosion under natural rainfall conditions. iForest – Biogeosciences and Forestry, 7 (2), 110–114. doi: https://doi.org/10.3832/ifor0845-007
  5. Shvebs, G. I., Liseckiy, F. N. (1989). Proektirovanie konturno-meliorativnoy sistemy pochvozashchitnogo zemledeliya. Zemledelie, 2, 55–58.
  6. Montgomery, D. R. (2007). Soil erosion and agricultural sustainability. Proceedings of the National Academy of Sciences, 104 (33), 13268–13272. doi: https://doi.org/10.1073/pnas.0611508104
  7. Lipkovich, I. E. (2013). Agrolandshaft i mashinoispol'zovanie. Mekhanizaciya i elektrifikaciya sel'skogo hozyaystva, 11, 2–4.
  8. El Khalil, H., El Hamiani, O., Bitton, G., Ouazzani, N., Boularbah, A. (2007). Heavy metal contamination from mining sites in South Morocco: Monitoring metal content and toxicity of soil runoff and groundwater. Environmental Monitoring and Assessment, 136 (1-3), 147–160. doi: https://doi.org/10.1007/s10661-007-9671-9
  9. Ghosh, P., Mahanta, S. (2014). Carbon sequestration in grassland systems. Range Management and Agroforestry, 35 (2), 173–181.
  10. Mello, C. R. de, Norton, L. D., Pinto, L. C., Beskow, S., Curi, N. (2016). Agricultural watershed modeling: a review for hydrology and soil erosion processes. Ciência e Agrotecnologia, 40 (1), 7–25. doi: https://doi.org/10.1590/s1413-70542016000100001
  11. Gorshkova, A. T., Urbanova, O. N., Karimova, A. I. (2015). The main stages of the modeling of river flow with a catchment area of less than 10 km2. Mezhdunarodniy nauchno-issledovatel'skiy zhurnal, 8 (39), 66–71.
  12. Sidorchuk, A. Y. (2015). Fractal geometry of the river network. Geomorphology RAS, 1, 3–14. doi: https://doi.org/10.15356/0435-4281-2014-1-3-14
  13. Miller, M. E., MacDonald, L. H., Robichaud, P. R., Elliot, W. J. (2011). Predicting post-fire hillslope erosion in forest lands of the western United States. International Journal of Wildland Fire, 20 (8), 982. doi: https://doi.org/10.1071/wf09142
  14. Carretier, S., Tolorza, V., Rodríguez, M. P., Pepin, E., Aguilar, G., Regard, V. et. al. (2014). Erosion in the Chilean Andes between 27°S and 39°S: tectonic, climatic and geomorphic control. Geological Society, London, Special Publications, 399 (1), 401–418. doi: https://doi.org/10.1144/sp399.16
  15. Buscarnera, G., Di prisco C. (2011). Stability criteria for unsaturated shallow slopes. Géotechnique Letters, 1 (4), 85–90. doi: https://doi.org/10.1680/geolett.11.00034
  16. Chalov, R. S., Ruleva, S. N., Mikhailova, N. M. (2016). Assessing the morphodynamical complexity of a large river in planning hydroeconomic measures (as exemplified by the Ob’). Geography and Natural Resources, 37 (1), 9–17. doi: https://doi.org/10.1134/s1875372816010029
  17. Sysuev, V. A., Maksimov, I. I., Maksimov, V. I., Alekseev, V. V. (2013). Vodosbornaya ploshchad' malyh rek kak ob'ekt antropogennogo agrolandshafta (na primere reki Civil'). Agrarnaya nauka Evro-Severo-Vostoka, 5 (36), 59–65.
  18. Maksimov, I. I., Maksimov, V. I., Vasil’ev, S. A., Alekseev, V. V. (2016). Simulation of channel development on the surface of agrolandscapes on slopes. Eurasian Soil Science, 4, 514–519. doi: https://doi.org/10.7868/s0032180x16040080
  19. Alekseev, V. V., Maksimov, I. I. (2013). Aerodinamicheskiy metod polucheniya osnovnoy gidrofizicheskoy harakteristiki pochv. Pochvovedenie, 7, 822–828.
  20. Maksimov, I. I., Maksimov, V. I., Vasil'ev, S. A. (2005). Sposob opredeleniya gidravlicheskih poter' na trenie: Pat. No. 2292539 RF. declareted: 29.07.2005; published: 27.01.2007, Bul. No. 3.
  21. Vasil’ev, S., Maksimov, I., Alekseev, E., Mihaylov, A. (2017). Method for determining the direction of water flow motion on agrolandscape of slope land. Vestnik of Kazan State Agrarian University, 12 (4), 72–77. doi: https://doi.org/10.12737/article_5a5f0f23dac509.14552207

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Published

2018-11-29

How to Cite

Alekseev, V., Maksimov, V., Chuchkalov, S., Medvedev, V., Mishin, P., Kazakov, Y., Kondratieva, N., Lekomtsev, P., Yunusov, G., & Obolensky, N. (2018). Development of a criteria­based approach to agroecological assessment of slope agrolandscapes. Eastern-European Journal of Enterprise Technologies, 6(10 (96), 28–34. https://doi.org/10.15587/1729-4061.2018.148623

Issue

Vol. 6 No. 10 (96) (2018): Ecology

Section

Ecology

License

Copyright (c) 2018 Victor Alekseev, Vladimir Maksimov, Sergey Chuchkalov, Vladimir Medvedev, Petr Mishin, Yurij Kazakov, Nadezhda Kondratieva, Petr Lekomtsev, Gubeydulla Yunusov, Nikolaj Obolensky

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