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PRACA ORYGINALNA
Liming effect on soil organic matter quality in grassland
 
Więcej
Ukryj
1
Faculty of AgriSciences, Department of Agrochemisty. Soil Sciences, Microbiology and Plant Nutritions, Department of Soil Sciences, Mendel University in Brno, Czech Republic
 
2
Agricultural Research, Ltd., Research Institute for Fodder Crops, Ltd. Troubsko, Czech Republic
 
3
Division of Crop Management Systems, Crop Research Institute, Prague, Czech Republic
 
 
Data nadesłania: 20-04-2023
 
 
Data ostatniej rewizji: 20-06-2023
 
 
Data akceptacji: 05-07-2023
 
 
Data publikacji online: 05-07-2023
 
 
Data publikacji: 08-09-2023
 
 
Autor do korespondencji
Luboš Sedlák   

Faculty of AgriSciences, Department of Agrochemisty. Soil Sciences, Microbiology and Plant Nutritions, Department of Soil Sciences, Mendel University in Brno, Czech Republic
 
 
Soil Sci. Ann., 2023, 74(2)169271
 
SŁOWA KLUCZOWE
STRESZCZENIE
Global carbon storage in soils is widely discussed today because of climate uncertainty and maintaining sustainable agricultural production. Human intervention in agricultural or energy production poses many changes in soil management, which highly affects soil quality/health. Permanent grasslands fulfil a wide range of ecosystem functions and have a high potential for increasing arable land. Today, grasslands are becoming more and more intensively used, fertilized and disturbed. Optimizing their management is essential to maintain a resilient and stable ecosystem. The produced biomass is used as a forage or for energy production. We aimed at the impact of long-term grassland liming on the total content of soil organic carbon (SOC), humic substances (CHS), and microbial biomass (Cmic). Furthermore, soil reaction and available nutrient content were evaluated. Soil samples were collected from a split-plot field experiment at Mendel University in Brno (locality Kameničky). The soil was classified as Dystric Planosol Siltic, medium textured, strongly acidic, with high soil organic carbon content. The yearly liming rate was 1.4 t/ha CaO. The linkage between the soil pH, SOC, Cmic, and available nutrient content was evaluated by the multivariate exploratory techniques and regression models. Results showed that long-term liming affects both soil biota and carbon storage.
 
REFERENCJE (42)
1.
Aitken R.L., Moody, P.W., McKinley, P.G., 1990. Lime requirement of acid Queensland soils. Relationship between soil properties and pH buffer capacity. Australian Journal of Soil Resarch 28 (5), 695-701.
 
2.
Beneš, J., 2013. Origin and history of grasslands in Central Europe – a review. Grass and Forage Science 68, 345-363. https://doi.org/10.1111/gfs.12....
 
3.
Blanchet, G., Gavazov, K., Bragazza, L., Sinaj, S., 2016. Responses of soil properties and crop yields to different inorganic and organic amendments in a Swiss conventional farming system. Agriculture, Ecosystems and Environment 230, 116-126. https://doi.org/10.1016/j.agee....
 
4.
Bordonal, R.O., Lal, R., Ronquim, C.C., De Figueiredo, E.B., Carvalho, J.L.N., Maldonado, W. Jr., Milori, D.M.B.P., La Scala, J.N., 2017. Changes in quantity and quality of soil carbon due to the land-use conversion to sugarcane (Saccharum officinarum) plantation in southern Brazil. Agriculture, Ecosystems and Environment 240, 54-65. https://doi.org/10.1016/j.agee....
 
5.
Condron, L., Stark, C., O´Callghan, M., Clinton, P., Huang, Z., 2010. The role of microbial communities in the formation and decomposition of soil organic matter. [In:] Dixon, G.R., Tilson, E. J. (Eds.): Soil Microbiology and Sustainable Crop production. SprongerNetherlands, Dordrecht, 81-118. http://refhub.elsevier.com/S01....
 
6.
Dai, Z., Su, W., Chen, H., Barberan, A., Zhao, H., Yu, M., Yu, L., Brookes, P.C., Schadt, C.W., Chang, S.X., Xu, J., 2018. Long-term nitrogen fertilization decreases bacterial diversity and favours the growth of Actinobacteria and Proteobacteria in agroecosystems across the globe. Global Change Biology 24(8), 3452-3461.
 
7.
Decree No. 275/1998 Coll. https://www.aspi.cz/products/l... (In Czech).
 
8.
Deng, L., Zhu, G. Y., Tang, Z.S., Shang Guan, Z.P.,2016. Global patterns of the effect of land use changes on soil carbon stocks. Global Ecology Biogeography 5, 127-138.
 
9.
Duffkova, R., Kvítek, T., Voldřichová, J., 2005. Soil organic carbon and nitrogen characteristics in differently used grasslands at sites with drainage and without drainage. Plant Soil and Environment 51(4), 165-172.
 
10.
Filep, T., Szili-Kovacs, T., 2010. Effect of liming on microbial biomass carbon of acidic arenosol in pot experiment. Plant Soil and Environment 56 (6), 268-273.
 
11.
Frank, T., Zimmermann, I., Rhorn, N., 2019. The need for lime in dependence on clay content in arable crop production in Germany. Soil and Tillage Research 191, 11-17. https://doi.org/10.1016/j.stil....
 
12.
Hejcman, M., Schellberg, J., Pavlů, V., 2010. Long-term effects of cutting frequency and liming on soil chemical properties, biomass production and plant species composition of Lolio-Cynosuretum grassland after the cessation of fertilizer application. Applied Vegetation Science 13, 257-269. https://doi.org/10.1111/j.1654....
 
13.
Hobley, E.U., Baldock, J., Wilson, B., 2016. Environmental and human influences on organic carbon fractions down the soil profile. Agriculture Ecosystems and Environment 223, 142-166.
 
14.
Holland, J., Bennett, A., Newton, A., White, P., McKenzie, B., George, T., 2018. Liming impact on soil, crops, and biodiversity in the UK: A review. The Science of the Total Environment 610-611, 316-332. https://doi.orgg/101016/j.scit....
 
15.
Horáková, E, Pospíšiloví, L., Vlček, V., Menšík, L., 2020. Changes in soil biological and chemical properties due to the land-use conversion. Soil and Water Research 15 (4), 228-236. https://doi.org/10.17221.
 
16.
Chen, X., Chen, H. Y. H., Chen, Ch., Ma, Z., Searle, E. B., Yu, Z., Huang, Z., 2020. Effects of plant diversity on soil carbon in diverse ecosystems: a global meta-analysis. Biological Reviews 95, 167-183.
 
17.
ISO 13878:1998 Sys Review (6-2003) Soil quality – Determination of total nitrogen content after dry combustion („elemental analysis“). https://www.iso.org/standard/2....
 
18.
IUSS Working Group WRB World Reference Base for Soil Resources 2014, update 2015 International soil classification system for naming soils and creating legends for soil maps. World Soil Resources Reports No. 106. Publisher: FAOEditor: Peter Schad, Cornie van Huysteen, Erika Michéli. FAO, Rome.
 
19.
Kallenbach, C. M., Frey, S. D., Grandy, A. S., 2016. Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls. Nature Communications 7, 13630.
 
20.
Kononnova, M.M., Bělčíková, N.P., 1963. Short fractionation method of humic substances determination in mineral soils (Uskorennyj Metod Opredelenija Sostava Gumusa Mineralnych Počv). In: Soil organic matter (Organičeskoje Veščestvo Počvy). Moscow State University (Eds.): Moscow, Russia, 228-234.
 
21.
Lange, M., Eisenhauer, N., Sierra, C. A., Bessler, H., Engels, Ch., Griffiths, R. I., Mellado–Vázquez, P. G., Malik, A. A., Roy, J., Scheu, S., Steinbeiss, S., Thomson, B. C., Trumbore, S E., Gleixner, G., 2015. Plant diversity increases soil microbial activity and soil carbon storage. Nature Communications 6, 6707.
 
22.
Lehmann, J., Hansel , C.M., Kaiser, CH., Kleber, M., Maher, K., Manzoni, S.,  Nunan, N., Reichstein , M., Schimel, J.P., Torn, M.S., Wieder, W.R., Kögel-Knabner, I., 2020. Persistence of soil organic carbon caused by functional complexity. Nature Geoscience. https://doi.org/10.1038/s41561....
 
23.
Li, M., Hu, H., He, X., Jia, J., Drosos, M., Wang, G., Liu, F., Hu, Z., Xi, B., 2019. Organic Carbon Sequestration in Soil Humic Substances As Affected by Application of Different Nitrogen Fertilizers in a Vegetable-Rotation Cropping System. Journal of Agricultural and Food Chemistry 67, 3106–3113. https://doi:10.1021/acs.jafc.8....
 
24.
Mayel, S., Jarrah, M., Kuka, K.,2020. How does grassland management affect the physical and biochemical properties of temperate grassland soils? – a review study. Grass and Forage Science 76(2), 215-244. https://onlinelibrary.wiley.co....
 
25.
Meloun, M., Militký, J., 2011 Statistical Data Analysis, A Practical Guide with 1250 Exercises and Answer key on CD; Woodhead Publishing India: New Delhi.
 
26.
Mosley, L. M., Willson, P., Hamilton, B., Butler, G., Seaman, R., 2015. The capacity of biochar made from common reeds to neutralise pH and remove dissolved metals in acid drainage. Environmental Science and Pollution Research 19, 15113-15122.
 
27.
Mehlich, A., 1984. Mehlich 3 soil test extractant: A modification of Mehlich 2 extractant. Communications in Soil Science and Plant Analysis 15, 1409-1416.
 
28.
Nelson, D.W., Sommers, L.E., 1996. Total carbon, organic carbon and organic matter. In: Sparks DL (Ed.). Methods of soil analysis. Part 3. Chemical methods. Madison: Soil Science Society of America. 961-1010.
 
29.
Němeček, J., Muhlhanselová, M., Macků J., Vokoun, J., Vavříček, D., Novák, P., 2011. Taxonomický klasifikační systém půd České republiky. 2nd ed, Praha: Česká zemědělská univerzita. (In Czech).
 
30.
Ondrasek, G., Bakić Begić, H., Zovko, M., Filipović, L., Meriňo-Gergichevich, C., Savić, R., Rengel, Z., 2019. Biogeochemistry of soil organic matter in agroecosystems & environmental implications. Science of the Total Environment 658, 1559–1573, https://doi:10.1016/j.scitoten....
 
31.
Paradelo, R., Virto, I., Chenu, C., 2015. Net effect of liming on soil organic carbon stocks: A review. Agriculture, Ecosystems 202 (2), 98-107. https://10.1016/j.agee.2015.01....
 
32.
Sapek, B., Burzyńska, I., 1996. Effects of liming on organic carbon content inmineral soil of a permanent grassland. Polish Journal of Soil Science 29, 113-120.
 
33.
Sollenberger, L.E., Kohmann, M.M., Dubeux, J.C., Silveira, M.L., 2019. Grassland management affects delivery of regulating and supporting ecosystem services. Crop Science 59, 441-459. https://doi.org/10.2135/cropsc....
 
34.
Song, X., Liu, S., Liu, Q., Zhang, W., Hu, C., 2014. Carbon Sequestration in Soil Humic Substances Under Long-Term Fertilization in a Wheat-Maize System from North China. Journal of Integrative Agriculture 13, 562–569. https://doi.org/10.1016/S2095-....
 
35.
Sparks, D., 2003. Environmental Soil Chemistry, 2nd ed.; Academic Press, an Imprint of Elsevier: San Diego, CA, USA.
 
36.
Spohn, M., Klaus, K., Wanek, W., Richter, A., 2016. Microbial carbon use efficiency and biomass turnover depending on soil depth: Implications for carbon cycling. Soil Biology and Biochemistry 96, 74-81.
 
37.
Tang, J., Riley, W. JK., 2015. Weaker soil carbon–climate feedbacks resulting from microbial and abiotic interactions. Nature Climate Change 5, 56-60.
 
38.
Upjohn, B., Fenton, G., Conyers, M., 2005. Soil acidity and liming. Agfact AC. 19, 3rd edition, State of New South Wales.
 
39.
Vance, E.D., Brookes, P.C., Jenkinson, D.S., 1987. An extraction method for measuring soil microbial biomass C. Soil Biology and Biochemistry 19, 703-707.
 
40.
Zbíral, J., 2016. Standard Working Procedures of the Central Institute for Supervising and Testing in Agriculture (CISTA). Soil Analysis I. Method 30074.1. CISTA (Eds.) Brno.
 
41.
Zhao, S., Qiu, S., Cao, C., Zheng, C., Zhou, W., He, P., 2014. Responses of soil properties, microbial community and crop yields to various rates of nitrogen fertilization in a wheat-maize cropping system in north-central China. Agriculture Ecosystem and Environment 194, 29-37. http://dxdoi.org/10.1016/j.age....
 
42.
Zhao, Z.B., He, J.Z., Quan, Z., Wu, C.F., Sheng, R., Zhang, L.M., Geiseng, S., 2020. Fertilization changes soil microbiome functioning, especially phagotrophic protists. Soil Biology and Biochemistry 148, 107863.
 
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