Long-term fire effects of the drained open fen on organic soils

Journal title

Archives of Environmental Protection




vol. 43


No 1



wetland fire ; peat fire ; fen ; wildfire

Divisions of PAS

Nauki Techniczne


Polish Academy of Sciences




Artykuły / Articles


DOI: 10.1515/aep-2017-0002 ; ISSN 2083-4772 ; eISSN 2083-4810


Archives of Environmental Protection; 2017; vol. 43; No 1


Kimura (2011), Fire severity affects vegetation and seed bank in a wetland, Applied Vegetation Science, 14, 350, ; Qian (2009), Effects of burn temperature on ash nutrient forms and availability from cattail ( Typha domingensis ) and sawgrass ( Cladium jamaicense ) in the Florida Everglades, Journal of Environmental Quality, 38, 451, ; Wassen (1995), Hydrology water chemistry and nutrient accumulation in the Biebrza fens and floodplains, Wetlands Ecology and Management, 3, 125, ; Schrautzer (2013), Characterizing and evaluating successional pathways of fen degradation and restoration, Ecological Engineering, 25, 108. ; Grygoruk (2015), Assessing habitat exposure to eutrophication in restored wetlands : Model - supported ex - ante approach to rewetting drained mires, Journal of Environmental Management, 5, 152. ; Marcos (2007), Changes in a humic cambisol heated under laboratory conditions : The significance of heating time, Geoderma, 100, 500. ; Tiemeyer (2007), A comprehensive study of nutrient losses soil properties and groundwater concentrations in a degraded peatland used as an intensive meadow implications for re - wetting, Journal of Hydrology, 345, 80, ; McEachern (2000), Forest fire induced impacts on phosphorus nitrogen and chlorophyll a concentrations in boreal subarctic lakes of northern Alberta, Canadian Journal of Fisheries and Aquatic Sciences, 57, 73, ; Olila (1997), Influence of draining on soil phosphorus forms and distribution in a constructed wetland, Ecological Engineering, 9, 157, ; Zak (2008), Evaluation of phosphorus mobilization potential in rewetted fens by an improved sequential chemical extraction procedure, European Journal of Soil Science, 59, 1191, ; Sala (2000), Methods of estimating aboveground net primary productivity in Ecosystem Science, Methods, 31. ; Turetsky (2015), van der Global vulnerability of peatlands to fire and carbon loss, Nature Geoscience, 8, 11, ; Klimkowska (2010), van Species trait shifts in vegetation and soil seed bank during fen degradation, Plant Ecology, 206, 59, ; Mars (1996), De The effect of drainage and management on peat chemistry and nutrient deficiency in the former Jegrznia - floodplain, Vegetatio, 126, 59. ; Rein (2008), The severity of smouldering peat fires and damage to the forest soil, Catena, 74, 304, ; Zak (2014), How helophytes influence the phosphorus cycle in degraded inundated peat soils Implications for fen restoration, Ecological Engineering, 66, 82, ; Dikici (2006), Peat fire effects on some properties of an artificially drained peatland, Journal of Environmental Quality, 35, 866, ; Verhoeven (1996), Nitrogen - or phosphorus - limited growth in herbaceous wet vegetation : Relations with atmospheric inputs and management regimes Trends in, Ecology & Evolution, 11, 494, ; DeBano (2000), The role of fire and soil heating on water repellency in wildland environments review, Journal of Hydrology, 231. ; Laiho (1995), Changes in mineral element concentrations in peat soils drained for forestry in Finland, Scandinavian Journal of Forest Research, 10, 218, ; Sundström (2000), Nutrient conditions in drained peatlands along a north - south climatic gradient in Sweden, Forest Ecology and Management, 126, 149, ; Neary (1999), Fire effects on belowground sustainability review and synthesis, Forest Ecology and Management, 122, 51, ; Zak (2010), Phosphorus mobilization in rewetted fens : The effect of altered peat properties and implications for their restoration, Ecological Applications, 20, 1336, ; Wang (2015), Effect of fire on phosphorus forms in Sphagnum moss and peat soils of ombrotrophic bogs, Chemosphere, 119, 1329, ; Egner (1960), Studies on chemical soil analysis as the basis for the assessment of nutrient status of soil II : Chemical extraction methods for phosphorus and potassium determination Kungliga Lantbrukshügskolans ( in German, Annaler, 26, 199. ; Venterink (2009), Long - term effects of drainage and hay - removal on nutrient dynamics and limitation in the Biebrza mires, Biogeochemistry, 93, 235, ; Qian (2009), Estimation of postfire nutrient loss in the Florida everglades, Journal of Environmental Quality, 38, 1812, ; Laubhan (1995), Effects of prescribed fire on moist - soil vegetation and soil macronutrients, Wetlands, 15, 159, ; Arocena (2003), Prescribed fire - induced changes in properties of sub - boreal forest soils, Geoderma, 113, 1, ; Zak (2007), The mobilisation of phosphorus organic carbon and ammonium in the initial stage of fen rewetting ( a case study from NE Germany ), Biogeochemistry, 85, 141, ; Davies (2013), Peat consumption and carbon loss due to smouldering wildfire in a temperate peatland, Forest Ecology and Management, 308, 169, ; Mętrak (2006), Geochemical changes of peat soils and plant succession on the deeply burnt mires, Polish Journal of Environmental Studies, 15, 57. ; Holden (null), Artificial drainage of peatlands : hydrological and hydrochemical process and wetland restoration, Progress in Physical Geography, 28, 95, ; Benscoter (2003), Variability in organic matter lost by combustion in a boreal bog during the Chisholm fire, Canadian Journal of Forest Research, 33, 2509, ; Middleton (2006), van Biodiversity management of fens and fen meadows by grazing cutting and burning, Applied Vegetation Science, 9, 307, ; Lijklema (1980), Interaction of orthophosphate with iron ( III ) and aluminum hydroxides and Technology, Environmental Science, 14, 537, ; Ketterings (2000), Soil color as an indicator of slash - and - burn fire severity and soil fertility in Sumatra Indonesia, Soil Science Society of America Journal, 64, 1826, ; Laine (1995), Long - term effects of water level drawdown on the vegetation of drained pine mires in southern Finland, Journal of Applied Ecology, 32, 785, ; Mętrak (2008), Plant secondary succession patterns after wildfire in the Biebrza National Park, Phytopedon, 7, 109. ; Certini (2005), Effects of fire on properties of forest soils review, Oecologia, 143, 1, ; Watts (2013), Smoldering combustion and ground fires, Fire Ecology, 9, 124, ; Smith (2001), Differential effects of surface and peat fire on soil constituents in a degraded wetland of the northern Florida Everglades, Journal of Environmental Quality, 30, 1998, ; Sapek (2008), Phosphate and ammonium concentrations in groundwater from peat soils in relation to the water table, Polish Journal of Soil Science, 41, 139. ; Campbell (1995), Jungbauer Soil temperature and water content beneath a surface fire, Soil Science, 6, 159. ; Flores (2011), Does prescribed fire benefit wetland vegetation ?, Wetlands, 31, 35, ; Giovannini (1990), Effects of heating on some chemical parameters related to soil fertility and plant growth, Soil Science, 149, 344,

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