Validation of water erosion prediction methodology by actual changes in fertility indicators of agro-sod-podzolic soil

The article presents the results of the computational method for determining the potential danger of water erosion and quantitative agrophysical and agrochemical indicators obtained by traditional methods of their direct measurement. When calculating losses as a result of water erosion in agro-sodpodzolic loamy weak eroded soil, the universal soil loss equation of Wischmeier and Smith (1965) was used, the variables in which are the erosive power of precipitation, erosiveness of soil, length and steepness of slope, character of vegetative ground cover and influence of erosion control soil protection measures. The obtained values of soil losses from 1,8 to 12,1 t/ha a year are confirmed by the change of soil organic matter content during the rotation of six-course grain-grass-fallow crop rotation from 2,48 to 1,65% according to I.V. Tyurin depending on agrochemical background as well as soil density 1,31–1,60 g/cm3, its structural state and content of microaggregates unstable to water erosion from 7,3 to 14,6%. The dependence of the selected informative signs on the system of main tillage of agrosod- podzolic loamy soil has been determined. Сlose correlations between the content of microaggregates and soil density (r = – 0,49) and the content of organic matter related to it (r = – 0,74) were established. The analysis of variance allowed to trace the influence of the main tillage system on the accumulation and distribution of in the arable horizon at different levels of the fertility of the agro-sod-podzolic loamy soil. The more intensive development of erosion processes at the annual plowing was revealed.

1. Varaksina E.G., Zaharova T.I. Eroziia i vosproizvodstvo plodorodiia erodirovannykh pochv v Udmurtii: monografiia [Erosion and fertility reproduction of eroded soils in Udmurtia: monograph] // Izhevsk: FGOU VPO Izhevskaia GSKhA, 2008. – 432 s. (in Rus.)

2. Dzhamalov A.T., Ragimov Prognozirovanie erozionnykh protsessov pochv na marshrutakh prokladki magistral’nykh truboprovodov na osnove Geoinformatsionnykh tekhnologii i kosmicheskikh snimkov vysokogo razresheniia [Prediction of erosion processes of soil on the routes of the main pipelines on the basis of geo-information technologies and satellite images of high resolution] // Sistemni doslidzhennia ta informatsiini tekhnoloii – 2011. – № 4. – S. 97–103. (in Rus.)

3. GOST 17.4.4.03–86. Okhrana prirody. Pochvy. Metod opredeleniia potentsial’noi opasnosti erozii pod vozdeistviem dozhdei: data vvedeniia 1987–07–01. [Nature Conservation. Soils. Method for determining the potential danger of erosion by rainfall: date of introduction 1987–07–01] // M.: Standartinform, 2008. (in Rus.)

4. Kiriushin V.I. Ekologizatsiia zemledeliia i tekhnologicheskaia politika. [Ecologization of agriculture and technological policy] // M.: Izd-vo MSKhA, 2000. – 473 s. (in Rus.)

5. Larionov G.A. Eroziia i defliatsiia pochv: osnovnye zakonomernosti i kolichestvennye otsenki [Soil erosion and deflation: basic laws and quantitative assessments] // M.: Izd-vo Mosk. un-ta, 1993–200 s.

6. Logachev I.A., Cybul’ko N.N., Cyribko V.B., Ustinova A.M., Kas’yanenko I.I. Pedotransfernye funktsii strukturnogo sostoianiia i ustoichivosti k erozii dernovo-podzolistykh pochv, sformirovannykh na lessovidnykh suglinkakh [Pedotransfer functions of structural condition and resistance to erosion sod-podzolic soils formed on loess-like loam] // Pochvovedenie i agrokhimiia, 2021. – № 1(66). – S. 42–50 (in Rus.)

7. Pochvozashchitnye tekhnologii i sovremennye malozatratnye tekhnologicheskie priemy vozdelyvaniia sel’skokhoziaistvennykh kul’tur: Rekomendatsii. [Soil-protective technologies and modern low-cost technological methods of cultivation of crops: Recommendations] // M.: FGNU «Rosinformagrotekh», 2001. – 28 s. (in Rus.)

8. Travnikova L.S., Artem’eva Z.S., Sorokina N.P. Raspredelenie granulometricheskikh fraktsii v dernovo-podzolistykh pochvakh, podverzhennykh ploskostnoi erozii [Distribution of granulometric fractions in sod-podzolic soils subjected to planar erosion] // Pochvovedenie, 2010. – № 4. – S. 495–504. (in Rus.)

9. Tronina L.O. Minimizatsiia obrabotki dernovo-podzolistoi suglinistoi pochvy pri raznom urovne plodorodiia: monografiia [Minimization of tillage of sod-podzolic loamy soil at different fertility levels: monograph] // Izhevsk: Alkid, 2021. – 164 s. (in Rus.)

10. Kholzakov V.M. Povyshenie produktivnosti dernovo-podzolistykh pochv v Nechernozemnoi zone: monografiia [Increase of productivity of sod-podzolic soils in the Non-Black Earth zone: monograph] // Izhevsk: FGOU VPO Izhevskaia GSKhA. – 2006. – 436 s. (in Rus.)

11. Kirkby M.J., Morgan R.P. SOIL EROSION / Eroziia pochvy [Soil erosion / translated from English and preface by M.F. Pushkarev] // M.: Kolos, 1984. – 415 s.