Changes in the biological activity of soils when adding superabsorbing polymers to them
https://doi.org/10.21266/2079-4304.2026.257.126-139
Abstract
Due to global climate change, which entails redistribution of intra-annual precipitation, there are continuous periods of draught, which were not typical for this territory before, which directly affects the water availability of agricultural crops. The solution of this problem is in development of various technologies and functional materials. One of such materials are superabsorbent polymers or hydrogels. Many studies prove that hydrogels favorably affect the yield of agricultural crops, due to their ability to absorb water in a volume exceeding its own in several tens of times, thereby retaining moisture in the root layer, preventing it from evaporating and flowing to deeper layers of soil. Three types of hydrogels were used in the experiment: «Ritin-10», «Aquasorb», «B415-K» – and sod-podzolic soil from the Menkovo branch of the Agrophysical Institute in the Leningrad region. Microbial metabolic coefficient (qCO2) is an integral indicator of the biological state of soils. It reflects the change in basal respiration and microbial biomass of the soil: the lower the value is, the better the condition of the microbial community is. In the control samples there was an increase in the value of the indicator by day 30, in the samples with hydrogels this indicator decreased by day 30. For all samples with hydrogels there was a noticeable decrease in the index and, consequently, an improvement in the state of microbiota occurred between day 15 and 18 of the experiment. In this experiment, is impossible to reliably establish whether hydrogel becomes available for microorganisms as a source of elements necessary for life activity, but its presence in the soil improves the state of microorganisms, and in case of hydrogel «B415-K» also contributes to the increase of biomass of microorganisms.
About the Authors
O. D. PozharskayaRussian Federation
Pozharskaya Olesya D. – PhD student, Department of Ecology, Anatomy and Physiology of Plants; Junior Researcher
AuthorID: 1143289
194021. Institute per. 5. St. Petersburg
199034. Universitetskaya emb. 5. St. Petersburg
Yu. V. Khomyakov
Russian Federation
Khomyakov Yuriy V. – PhD (Biological), Associate Professor, Department of Ecology, Anatomy and Physiology of Plants; Head of the Laboratory of Biochemistry of Soil and Plant Systems
194021. Institute per. 5. St. Petersburg
195220. Grazhdanskiy av. 14. St. Petersburg
T. N. Danilova
Russian Federation
Danilova Tatyana N. – DSc (Biological), Leading Researcher, Laboratory of Agro-climate
AuthorID: 672048
195220. Grazhdanskiy av. 14. St. Petersburg
K. M. Klyaus
Russian Federation
Klyaus Konstantin M. – Senior Researcher
199034. Universitetskaya emb. 5. St. Petersburg
References
1. Anderson J.P.E., Domsch K.H. A physiological method for the quantitative measurement of microbial biomass in soils. Soil Biol. Biochem., 1978, vol. 10, no. 3, pp. 215–221. DOI: 10.1016/0038-0717(78)90099-8.
2. Blagodatskiy S.A., Blagodatskaya E.V. Determination of microbial carbon content in soil based on respiratory response of microorganisms to glucose application. Methods of soil organic matter research. Vladimir, 2005, pp. 385-400. (In Russ.)
3. Danilova T.N., Tabynbayeva L.K. Polymer gels to manage water availability for wheat (Triticum aestivum L.) under various environment conditions. Sel’skokhozyaistvennaya biologiya, 2019, vol. 54, no. 1, pp. 76–83. DOI: 10.15389/agrobiology.2019.1.76rus. (In Russ.)
4. Dmitrakova Ia.A., Abakumov E.V. Microbial biomass and basal soil respiration of quarry-dumps systems with different substrates. Live and bio-abiotic systems, 2016, no. 16, art. no. 9. (In Russ.)
5. Kazakova N.A. Functional biodiversity of soil microorganisms. Vestnik of the Ulyanovsk State Agricultural Academy, 2009, no. 1 (8), pp. 27–29. (In Russ.)
6. Khaziev F.Kh. Functional role of enzymes in soil processes. Vestnik of the Academy of Sciences of the Republic of Bashkortostan, 2015, vol. 20, no. 2 (78), pp. 14-24. (In Russ.)
7. Maksimova Yu.G., Shchetko V.A., Maksimov A.Yu. Polymer hydrogels in agriculture (review). Sel’skokhozyaistvennaya biologiya, 2023, vol. 58, no. 1, pp. 23- 42. DOI: 10.15389/agrobiology.2023.1.23rus. (In Russ.)
8. Oksińska M.P., Magnucka E.G., Lejcuś K., Jakubiak-Marcinkowska A., Ronka S., Trochimczuk A.W., Pietr S.J. Colonization and biodegradation of the cross-linked potassium polyacrylate component of water absorbing geocomposite by soil microorganisms. Applied Soil Ecology, 2019, vol. 133, pp. 114-123. DOI: 10.1016/j.apsoil.2018.09.014.
9. Sojka R.E., Bjorneberg D.L., Entry J.A., Lentz R.D., Orts W.J. Polyacrylamide in agriculture and environmental land management. Advances in agronomy, 2007, vol. 92, pp. 75-162. DOI: 10.1016/S0065-2113(04)92002-0.
10. Stahl J.D., Cameron M.D., Haselbach J., Aust S.D. Biodegradation of superabsorbent polymers in soil. Environmental Science and Pollution Research, 2000, vol. 7, pp. 83-88. DOI: 10.1065/espr199912.014.
11. Wilske B., Bai M., Lindenstruth B., Bach M., Rezaie Z., Frede H.G., Breuer L. Biodegradability of a polyacrylate superabsorbent in agricultural soil. Environmental Science and Pollution Research, 2014, vol. 21, pp. 9453-9460. DOI: 10.1007/s11356-013-2103-1.
12. Zavyalova N.E., Vasbieva M.T., Fomin D.S. Microbial biomass, respiratory activity and nitrogen fixation in soddy-podzolic soils of the Pre-Urals Area under various agricultural uses. Soil Science, 2020, no. 3, pp. 372-378. DOI: 10.31857/S0032180X20030120. (In Russ.)
Review
For citations:
Pozharskaya O.D., Khomyakov Yu.V., Danilova T.N., Klyaus K.M. Changes in the biological activity of soils when adding superabsorbing polymers to them. Izvestia Sankt-Peterburgskoj lesotehniceskoj akademii. 2026;1(257):126-139. (In Russ.) https://doi.org/10.21266/2079-4304.2026.257.126-139
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