A Stagnosol in the World Reference Base for Soil Resources (WRB) is soil with strong mottling of the soil profile due to redox processes caused by stagnating surface water.

Stagnosol (Ah-Bg1-Bgc-Bg2) showing pooled water

Stagnosols are periodically wet and mottled in the topsoil and subsoil, with or without concretions and/or bleaching. The topsoil can also be completely bleached (albic horizon). A common name in many national classification systems for most Stagnosols is pseudogley. In the USDA soil taxonomy, many of them belong to the Aqualfs, Aquults, Aquents, Aquepts and Aquolls.

They are developed in a wide variety of unconsolidated materials like glacial till, and loamy aeolian, alluvial and colluvial deposits and physically weathered siltstone. Stagnosols occur on flat to gently sloping land in cool temperate to subtropical regions with humid to perhumid climate conditions.

The agricultural suitability of Stagnosols is limited because of their oxygen deficiency resulting from stagnating water above a dense subsoil. Therefore, they have to be drained. However, in contrast to Gleysols, drainage with channels or pipes is in many cases insufficient. It is necessary to have a higher porosity in the subsoil in order to improve the hydraulic conductivity. This may be achieved by deep loosening or deep ploughing. Drained Stagnosols can be fertile soils owing to their moderate degree of leaching.

Stagnosols cover 150–200 million ha worldwide. For the greater part in humid to perhumid temperate regions of West and Central Europe, North America, southeast Australia and Argentina. Here Stagnosols are associated with Luvisols as well as silty to clayey Cambisols and Umbrisols. They also occur in humid to perhumid subtropical regions, where they are associated with Acrisols and Planosols. with a light-coloured, coarse-textured, surface horizon that shows signs of periodic water stagnation and abruptly overlies a dense, slowly permeable subsoil with significantly more clay than the surface horizon. In the US Soil Classification of 1938 used the name Planosols, whereas its successor, the USDA soil taxonomy, includes most Planosols in the Great Groups Albaqualfs, Albaquults and Argialbolls.

See also

References

  • IUSS Working Group WRB: World Reference Base for Soil Resources, fourth edition. International Union of Soil Sciences, Vienna 2022. ISBN 979-8-9862451-1-9 ().

    Further reading

    • Kooijman, A.M. (2010). "Litter quality effects of beech and hornbeam on undergrowth species diversity in Luxembourg forests on limestone and decalcified marl". Journal of Vegetation Science. 21 (2): 248–261. doi:10.1111/j.1654-1103.2009.01138.x. ISSN 1100-9233.
    • Kovacevic, V.; Banaj, D.; Antunovic, M.; Bukvic, G. (2002). "Influences of genotype and soil properties on corn potassium and magnesium status". Plant Nutrition. Vol. 92. pp. 90–91. doi:10.1007/0-306-47624-X_43. ISBN 978-0-7923-7105-2.
    • Prietzel, Jörg; Thieme, Jürgen; Paterson, David (2010). "Phosphorus speciation of forest-soil organic surface layers using P K-edge XANES spectroscopy". Journal of Plant Nutrition and Soil Science. 173 (6): 805–807. doi:10.1002/jpln.201000248. ISSN 1436-8730.
    • Ehrmann, Otto; Puppe, Daniel; Wanner, Manfred; Kaczorek, Danuta; Sommer, Michael (2012). "Testate amoebae in 31 mature forest ecosystems – Densities and micro-distribution in soils". European Journal of Protistology. 48 (3): 161–168. doi:10.1016/j.ejop.2012.01.003. ISSN 0932-4739. PMID 22342135.
    • Vieten, B.; Conen, F.; Neftel, A.; Alewell, C. (2009). "Respiration of nitrous oxide in suboxic soil". European Journal of Soil Science. 60 (3): 332–337. doi:10.1111/j.1365-2389.2009.01125.x. ISSN 1351-0754. S2CID 97292710.
    • W. Zech, P. Schad, G. Hintermaier-Erhard: Soils of the World. Springer, Berlin 2022, Chapter 3.3.5. ISBN 978-3-540-30460-9
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