The effect of long-term peatlands drainage on the properties of soils in microrelief in the Długie Mokradło bog (Central Sudetes – SW Poland)

Adam Bogacz

Abstract


The aim of the study was to assess the impact of long-term drainage on the morphology and selected properties of shallow peatland soils in microrelief. The study was conducted within strongly drained peatland (Długie Mokradło bog) located on elevated plateau in the Central Sudetes. The study area is covered  by spruce stands introduced by man. Long-term drainage has changed morphology of study soils which were classified as Ombric Fibric Dystric Histosols or Histic Dystric Gleysols. Some peat horizons were strongly silted. The depth of organic materials varied within the range 30-55 cm. Peat humification process showed greater - activity in surface horizons, than in a deeper ones. This phenomenon were especially visible in the shallow places in drainage ditches. Soil reaction was strongly acidic. In soil horizons in old drainage ditches higher values of effective cation exchange capacity (CECe) were recorded, whereas base saturation (BS) did not exceed 20%.


Keywords


peat soil, mountain peatland, Sudetes, old ditches, peat cores morphology

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References


Berry G.J., Jeglum J.K. 1991. Hydrology of drained and undrained black spruce peatlands: ground water table profiles and fluctuation. Forestry Canada, Ontario Region, COFRA Report 3307: 1-31.

Bogacz A., Roszkowicz M. 2010. Wpływ użytkowania leśnego na zmiany właściwości gleb organicznych w brzegowej części Krągłego Mokradła (Park Narodowy Gór Stołowych). Soil Science Annual 61, 2: 15-20 (in Polish).

Bojko O., Kabala C. 2015. Loss-on-ignition as an estimate of total organic carbon in the mountain soils. Polish Journal of Soil Science 47, 2: 71-79.

Braekke F.H. 1978. Afforestation on peatland in Norway. Proceedings of the IPS-Symposium, International Peat Society, Brumunddal, Norway. 73-96.

Chambers F. 1983. New application paleo ecological techniques: integrating evidence of arable activity in pollen peat and soil stratigraphy, Cefn Graenog, North Wales. In: Integrating the Subsistence Economy (ed.) by M. Jones, BAR International Series 181, Chapter 5, 16 pp.

Ciężkowski W., Kiełczawa B. 2008. Wody. [w]: A. Witkowski, B.M. Pokryszko, W. Ciężkowski (red.), Przyroda Parku Narodowego Gór Stołowych. Wyd. Parku Narodowego Gór Stołowych, Kudowa-Zdrój, 86–100 (in Polish).

Clymo R.S. 1983. Peat. Ecosystems of the World: Bog, Swamp, Moor and Fen, vol 4A. Ed. A. J. P. Gore. Amsterdam, Elsevier: 159-224.

Doerr S.H. 1998. On standardizing the Water Drop Penetrator Time and the Molarity of an Ethanol Droplet technique classify soil hydrophobicity: a case study using medium texture soils. Earth Surface Processes Landforms. 23: 663-668. http:// dx.doi.org/:0.1002/(SICI)1096-9837(199807)23:7<663::AID-ESP909>3.0.CO;2-6

Gawlik J. 2000. Division of differently sited peat formation into classes according to their state of secondary transformations. Acta Agrophysica 26: 17-24.

Glina B. 2014. Spatial diversity of shallow organic soils in the Stołowe Mountains as a result of anthropogenic transformation. Wrocław University of Life Sciences, Ph.D. thesis, Wrocław, Poland. 208 pp.

Glina B., Bogacz A., Gulyas M., Zawieja B., Gajewski P., Kaczmarek Z. 2016. Effect of long term forestry drainage on the current state of peatland soils. A case study from the Central Sudetes, SW Poland. Mires and Peat 18, 21: 1-11. http:// dx.doi.org/: 10.19189/MaP.2016.OMB.240

Glina B., Malkiewicz M., Mendyk Ł., Bogacz A., Woźniczka P. 2017. Human affected disturbances in vegetation cover and peatland development in the Holocene recorded in shallow mountain peatlands (Central Sudetes, SW Poland). Boreas, 46, 2: 381-390. http:// dx.doi.org/10.1111/bor.12203

Hokka H., Repola J., Laine J. 2008. Quantifying the interrelationship between tree stand growth rate and water table level in drained peatlands sites within Central Finland. Canadian Journal of Forest Research 38, 7: 1775-1783. http:// dx.doi.org/10.1139/X08-028

Ingram H.A.P. 1992. Introduction to the ecohydrology of mires in the context of cultural perturbation. [in:] Peatlands Ecosystem and Man: an Impact Assessment [ed.] by O.M. Brag, P.D. Hulme, H.A.P. Ingram, and R.A. Robertson. International Peat Society Finland, 676-693.

Jermaczek A., Wołejko L., Chapiński P. 2012. Mokradła Sudetów Środkowych i ich ochrona. Wydawnictwo Klubu Przyrodników, Świebodzin 51 pp.(in Polish).

Joensuu S., Ahti E., Vuollekoski M. 2002. Effects of Ditch Network Maintenance on the Chemistry of Run-off Water from Peatland Forests Scandinavian Journal of Forest Research, 17, 3: 238-247, http://dx.doi.org/10.1080/028275802753742909

Joensuu S., Ahti E., Vuollekoski M. 1999. The effects of peatland forest ditch maintenance on suspended solids in run off. Boreal Environmental Research 4: 335-343.

Kalisz, B., Łachacz, A. & Głażewski, R. 2015. Effects of peat drainage on labile organic carbon and water repellency in NE Poland. Turkish Journal of Agriculture and Forestry, 39: 20–27.

Laiho R. 2008. From a mire ecosystem to a drained peatlands. In: Korhonen R., Korpela L., Sarkkola S. (eds.) Finland-Fenland. Research and sustainable utilization of mires and peat. Finnish Peatland Society and Maahenki Ltd. 152-157.

Lynn W.C., McKinzie W.E., Grossman R.B. 1974. Field laboratory tests for characterization of Histosols. (in): Histosols: their characteristics, classification and use. (ed.: M. Stelly), SSSA Spec. Pub. 6 Madison, WI., 11-20.

Łachacz A., Nitkiewicz M., Kalisz B. 2009. Water repellency of post - boggy soils with a various content of organic matter. Biologia, 64, 3: 634–638, http:// dx.doi.org/10.2478/s11756-009-0096-5

Marttila H., Klove B. 2010. Dynamics of erosion and suspended sediment transport from drained peatland forests. Journal of Hydrology 388: 414-425, http:// dx.doi.org/10.1016/j.jhydrol.2010.05.026

Matyka-Sarzyńska D., Sokołowska Z. 2005. Physicochemical properties of mucks at different stage of secondary transformation, Acta Agrophysica, Monographies, 123: 1-69.

Migoń P., Latocha A., Parzóch K., Kasprzak M., Owczarek P., Witek M., Pawlik Ł. 2011. Contemporary geomorphic system of The Stołowe Mountains. [in:] Chodak T., Kabała C., Kaszubkiewicz J., Migon P., Wojewoda J. [ed.] Geoekologiczne Warunki Środowiska Przyrodniczego Parku Narodowego Gór Stołowych. WIND, Wrocław, 1-52. (in Polish).

Minayeva, T., Sirin, A., and Bragg, O. (Eds.) 2009. A Quick Scan of Peatlands in Central and Eastern Europe, Wetlands International, Wageningen, The Netherlands. 132 pp.

Minkinen K., Laine J. 1996. Effect of forest drainage on the peat bulk density and carbon stores of Finish mires’ julkaisussa. Proceedings of the International Workshop on “Northern Peatlands in Global Climatic Change”, Hyytiala, Finland, 8-12 October 1995, 1: 242-249. Publication of the Academy of Finland.

Nichols D.S., Boelter D.H. 1984. Fiber size distribution, bulk density, and ash content of peats in Minnesota, Wisconsin, and Michigan. Soil Science Society American Journal 48: 1322-1328. http:// dx.doi.org 10.2136/sssaj1984.03615995004800060024x

Nieminen M., Ahti E., Koivusalo H., Mattsson T., Sarkkola S., Laurén A. 2010. Export of suspended solids and dissolved elements from peatland areas after ditch network maintenance in south-central Finland. Silva Fennica 44, 1: 39-49. https://doi.org/10.14214/sf.161

Okruszko H. 1993. Transformation of fen-peat soil under the impact of draining. Zeszyty Problemowe Postępów Nauk Rolniczych, 406, 3-73. (in Polish).

Pakarinen P., Gorham E. 1984. Mineral element composition of Sphagnum fuscum peats collected from Minnesota, Manitoba and Ontario. Proc. Int. Symposium on Peat Utilization [ed.] C.H. Fuchsman and S.A. Spigarelli, Bemidji State University, Bemidji, Minnesota; October 10-13, 1984, 417-429.

Pietilainen O.P., Rekolainen S. 1991. Dissolved reactive and total phosphor load from agricultural and forest basins to surface water in Finland. Aqua Fennica 21: 127-136.

Prevost M., Plamondon A.P., Belleau P. 1999. Effects of drainage of a forested peatlands on water quality and quantity. Journal of Hydrology 214: 130-143. http://doi.org/10.1016/S0022-1694(98)00281-9

Rantonen H., Paivanen J. 1999. Silvicultural condition on tree stand after thinning on drained peatlands. Silva Fennica 23, 1: 33-50.

Rydin H., Jeglum J. 2006. The Biology of Peatlands. The biology of habitat series, Oxford University Press, 1-343.

Sallantaus T. 1988. Water quality of peatlands and man’s influence on it. In: Symposium On the Hydrology of Wetlands in Temperate and Cold Regions, 2, Joensuu, Publication of the Academy of Finland 5, Helsinki 80 pp.

Sarkkola S., Hokka H., Koivusalo H., Nieminen M., Ahti E., Paivanen J., Laine J. 2010. Role of tree stand evapotranspiration in maintaining satisfactory drainage condition in drained peatlands. Canadian Journal of Forest Research 40: 1485-1496. http:// dx.doi.org/10.1139/X10-084

Wang X., Westbrook C., Bedard-Haughn A. 2016. Effect of mineral horizons on spatial distribution of soil properties and N cycling in a mountain peatland. Geoderma, 273, 73-82. http://doi.org/10.1016/j.geoderma.2016.03.012

Van Rijn L.C. 1987. Mathematical modeling of morphological processes in the case of suspended sediment transport. Ph.D. thesis, Delft University of Technology, the Nederland’s.

Van Reeuwijk, L.P. 2002. Procedures for Soil Analysis. 6th edition. – Technical Paper/International Soil Reference and Information Centre, Wageningen, The Netherlands. 4 pp.

Varry E.S. 1988. The hydrology of wetlands and man’s influence on it. In: Symposium On the Hydrology of Wetlands in Temperate and Cold Regions, 2, Joensuu, Publication of the Academy of Finland 5, Helsinki 41-61




DOI: http://dx.doi.org/10.17951/pjss.2017.50.2.237
Date of publication: 2018-01-15 09:23:53
Date of submission: 2017-07-13 07:40:48


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