色控传媒

The studies related to the simultaneous measurement of CO₂ emissions from soils of different land use and its microbial properties are not carried out so often, and the results of such studies are largely contradictory. Therefore, to study the possible relationship between these indicators, 色控传媒soil scientists together with colleagues from the Institute of Chemical Physics and Technology of the Russian Academy of Sciences (Pushchino) analyzed the chernozem soils of the virgin steppe, broad-leaved forest, naked fallow and cities located in the forest-steppe zone of European Russia (Kursk region).

Transformation of natural ecosystems into arable land leads to a deterioration in the functioning of the soil microbial community and is expressed in a decrease in its amount and respiratory activity. Taking into account that at least half of the CO₂ emissions from the soil surface to the atmosphere is ensured by the respiration of soil microorganisms (CO₂ formation), and the transformation of terrestrial ecosystems is usually accompanied by a deterioration in the functioning of the soil microbial community (a decrease in biomass and inhibition of respiratory activity) and a decrease in the amount of available soil organic carbon, the soil scientists put forward a scientific hypothesis that there should be a certain interrelation between the emission of CO₂ from the soil and its microbial properties.

“Considering that the 小袨₂ emission from the soil is regulated by hydrothermal conditions (temperature, humidity), and its moisture is important for the soils of the steppe zone, the assessment of the microbial respiration of these soils during the growing season will reveal its interrelation with the emission flow of this gas,” says co-author of the article Kristina Ivashchenko from RUDN.

Every month from May to October, 色控传媒soil scientists were measuring measured in vivo the CO₂ emission of the chernozem of unmown steppe, forest (oak grove), naked fallow and meadow (located in the city). Soil CO₂ emissions were measured by a closed-chamber approach using an infrared gas analyzer. Immediately after measuring the emission activity of the soil, its samples were taken from the upper 10-centimeter layer, which were then delivered to the laboratory for measuring microbiological parameters. The carbon content of microbial biomass (C_MIC) was analyzed using the method of substrate-induced respiration, which is based on the respiratory response of soil microorganisms to the introduction of one of the main metabolites of decomposition of plant litter — glucose. Microbial respiration (MR) of soil microorganisms was determined in soil samples without plant roots, which were removed by sifting.

The content of C_MIC in the upper 10 cm soil layer in the studied ecosystems varied from 251 (naked fallow) to 1713 μg C g^-1 (forest). It turned out that in the soil of each ecosystem studied during the growing season, the content of C^MIC did not differ significantly. At the same time, C_MIC content of soil in undisturbed ecosystems (forest, steppe) turned out to be 3-5 times higher on average than in disturbed ones (city, naked fallow).

The MR of soil of forest, steppe, fallow, and urban areas ranged from 0.28 (fallow) to 1.81 μg CO₂ — C g^-1 h^-1 (forest). The MR of naked fallow and urban soils during the study period did not change; in the forest it was the highest in October, and in the steppe — in July and August. The MR in undisturbed ecosystems was 2–4 times higher than in disturbed ones (city, naked fallow).

The study demonstrated that 小袨₂ emission from the soil surface in the studied ecosystems has a positive correlation with the C_MIC content and MR of the upper 10-centimeter soil layer (r = 0.56 and 0.74, respectively). A regression analysis of the experimental data showed that CO₂ emission from the surface of chernozem of different land use during the growing season was determined by the C_MIC content by 52% and the MR value by 78%. In other words, the emission activity of chernozem of different land uses is associated with the enrichment of the soil by microorganisms and, to a greater extent, their respiratory activity, which, in turn, also depended on climatic conditions (temperature, humidity).

Thus, a close correlation and regression relationship were revealed between CO₂ emissions from soils of different types of land use and its microbial properties in the forest-steppe subzone of European Russia, which can be very useful for predicting this process in a certain territory with different ecosystems. The obtained experimental results can be used for more rational farming.

The article was published in .