PRACA ORYGINALNA
Features and assessment of decolorization of chernozems of Ukraine
Więcej
Ukryj
1
Faculty of Geograph/Department of Pedology and Geography of Soi, Ivan Franko National University of Lviv, Ukraine
2
Faculty of Natural Sciences and Economics/ Department of Geography and Methods of Teaching, Ivan Ohiienko National University of Kamianets-Podіlskyi, Ukraine
Data nadesłania: 29-12-2021
Data ostatniej rewizji: 14-02-2022
Data akceptacji: 19-03-2022
Data publikacji online: 19-03-2022
Autor do korespondencji
Yaroslav Vitvitskyi
Faculty of Geograph/Department of Pedology and Geography of Soi, Ivan Franko National University of Lviv, 41 Doroshenka St., 79000, Lviv, Ukraine
Soil Sci. Ann., 2022, 73(1)147483
SŁOWA KLUCZOWE
STRESZCZENIE
The article presents the results of colorimetry and practical study of the processes of decolorization of chernozems by using a scanner as one of the effective and available methods for assessing soil color at the macromorphological level. The influence of moisture on the objectivity of the color parameters of typical chernozem samples in the color space of the CIE L*a*b* system is experimentally analyzed. Based on the parameters of brightness (L*), red (a*) and yellow (b*) color components, the color differences of typical chernozems of arable land and adjacent forest belts were established, and the horizontal color heterogeneity of the arable horizon of plain and slope areas was determined. The results of the study indicate that chernozems undergo an intense change in the natural color on slopes with a steepness of ≥ 4%. In soil samples, an increase in the range of the chromatic index b* indicates a low humus content and an increase in the role of loess loams in the pigmentation of the arable horizon. Compared to arable land, soil samples of typical chernozem taken under forest belts are characterized by low brightness (L*) and high levels of humus. The obtained results show the possibility of using this approach to assess the quality state of chernozems. In addition, a direct study of the color of chernozems will allow obtaining data regardless of weather conditions, the presence of vegetation, and soil cultivation technology. The minimized influence of the external environment on the process of fixing the color parameters of the soil will contribute to the objectivity of information, which can later be used as an addition to the results of remote sensing. The formation of a digital database of color data will allow localizing areas of manifestation of decolorization of chernozems and assessing the risks associated with the soil management system.
REFERENCJE (25)
1.
Brown, P.E., O'Neal, A.M., 1923. The color of soils in relation to organic matter content. Research Bulletin (Iowa Agriculture and Home Economics Experiment Station) 5(75), 275–300.
2.
Dehtiar’ov, Y., Havva, D., Kovalzhy, N., Rieznik, S., 2021. Transformation of Physical Indicators of Soil Fertility in Typical Chernozem of the Eastern Forest-Steppe of Ukraine. In: Dmytruk Y., Dent D. (eds) Soils Under Stress. Springer, Cham.
https://doi.org/10.1007/978-3-....
3.
Dokuchaev, V.V., 1949. Russian chernozem. Publishing house of the USSR Academy of Sciences, Leningrad. (in Russian).
4.
Gorban, V.A., Khmelenko, O.V., Huslistyj, A.O., Tetiukha, O.G., 2019. Influence of forest vegetation on color, reflectivity and humus content in ordinary chernozems. Issues of steppe forestry and forest reclamation of soils 48, 25–37. (in Ukrainian with English abstract)
https://doi.org/10.15421/44190....
5.
Gunal, H., Ersahin, S., Yetgin, B., Kutlu, T., 2008. Use of Chromameter-Measured Color Parameters in Estimating Color-Related Soil Variables. Communications in Soil Science and Plant Analysis 39(5), 726–740.
http://dx.doi.org/10.1080/0010....
6.
Haskevych, V., 2017. Profile degradation of podzolic chernozem on the territory of Male Polissia. Visnyk of the Lviv University, Geography 51, 99–110. (in Ukrainian)
http://dx.doi.org/10.30970/vgg....
7.
Karavanova, E.I., 2003. Optical soils properties and their origin. MGU, Moscow. (in Russian).
9.
Kirillova, N.P., Sileva, T.M., Ul’yanova, T.Yu., Smirnova, I. E., Ul’yanova, A. S., Burova, E. K., 2018. Color Diagnostics of Soil Horizons (by the Example of Soils from Moscow Region). Eurasian Soil Science 51(11), 1363–1371.
https://doi.org/10.1134/S10642....
10.
Kirillova, N.P., Vodyanitskii, Y.N., Sileva, T.M., 2015. Conversion of soil color parameters from the Munsell system to the CIE-L* a* b* system. Eurasian Soil Science 48(5), 468–475.
https://doi.org/10.1134/S10642....
11.
Kirillova, N., Kemp, D., Artemyeva, Z., 2017. Colorimetric analysis of soil with flatbed scanners. European Journal of Soil Science 68(4), 420–433.
https://doi.org/10.1111/ejss.1....
12.
Kravchenko, Y.S., Tonkha, O.L., 2020. Morphogenesis of typical chernozem and izogumusol under longterm tillage use. Plant and Soil Science 11(2), 39–49. (in Ukrainian with English abstract)
https://doi.org/10.31548/agr20....
13.
Krupenikov, I.A., 1978. Chernozem – is our wealth. Chisinau. (in Russian).
14.
Krupenikov, I.A., 2008. Chernozems. Genesis, perfection, the tragedy of degradation, ways of protection and rebirth. Pontos, Chisinau. (in Russian).
15.
Mieczyński, T., 1931. Krótki podręcznik gleboznawstwa: praktyczne podręczniki rolnictwa i nauk pokrewnych. Wydawnictwo Tow. Oswiaty Rolniczej, Warszawa. (in Polish).
16.
Mokrzycki, W.S., Tatol M., 2012. Colour difference ∆E – A survey. Machine GRAPHICS & VISION 20 (4), 383–411.
17.
National standards of Ukraine, 2004. Soil quality. Methods for determination of organic matter (DSTU 4289). Kyiv. (in Ukrainian).
18.
Nosko, B.S., 2006. Anthropogenic evolution of chernozems. NSC ISSAR, Kharkiv. (in Ukrainian).
19.
Novykh, L.L., Chendev, Yu.G., 2014. Change in the morphological properties of chernozems in an agrosilvicultural landscape. Arid Ecosystems 4(1), 6–10.
https://doi.org/10.1134/S20790....
20.
Pankova, T.I., 2020. Dynamics of the agroecological state of typical chernozem under forest belts depending on the location in the relief (Kursk region, Russia). Environment and Human: Ecological Studies 10(1), 40–62. (in Russian)
https://doi.org/10.31862/2500-....
21.
Pardon, P., Reubens, B., Reheul D., Mertens, J., De Frenne, P., Coussement, T., Janssens, P., Verheyen, K., 2017. Trees increase soil organic carbon and nutrient availability in temperate agroforestry systems. Agriculture, Ecosystems & Environment 247, 98–111.
https://doi.org/10.1016/j.agee....
23.
Sharma, G., Wu, W., Dalal, E., 2005. The CIEDE2000 color-difference formula: implementation notes, supplementary test data, and mathematical observations. Color Research and Application 3, 21–30.
24.
Viscarra Rossel, R. A., Minasny, B., Roudier, P., McBratney, A. B., 2006. Colour space models for soil science. Geoderma 133, 320–337.
https://doi.org/10.1016/j.geod....
25.
Vodyanitskii, Yu. N., Kirillova, N. P., 2016. Application of the CIE-L*a*b* System to Characterize Soil Color. Eurasian Soil Science 11, 1337–1346. (in Russian)
http://dx.doi.org/10.7868/s003....