This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
AITKENHEAD J.A., McDOWELL W.H.C. 2000. Soil C:N ratio as a predictor of annual riverine DOC flux at local and global scales. Global Biochem Cy 14: 127-138AITKENHEADJ.A.McDOWELLW.H.C.2000Soil C:N ratio as a predictor of annual riverine DOC flux at local and global scalesGlobal Biochem Cy1412713810.1029/1999GB900083Search in Google Scholar
BANASZUK H. 2004. General description of Biebrza Valley and Biebrza National Park. In: Banaszuk H (ed) Biebrza Valley and Biebrza National Park, Wydawnictwo Ekonomia i Środowisko, Białystok (in Polish)BANASZUKH.2004General description of Biebrza Valley and Biebrza National ParkBanaszukH(ed)Biebrza Valley and Biebrza National Park, Wydawnictwo Ekonomia i ŚrodowiskoBiałystok(in Polish)Search in Google Scholar
BELLAMY P.H., LOVELAND P.J., BRADLEY R.I., LARK R.M., KIRK G.J.D. 2005. Carbon losses from all soils across England and Wales 1978-2003. Nature 437: 245-248BELLAMYP.H.LOVELANDP.J.BRADLEYR.I.LARKR.M.KIRKG.J.D.2005Carbon losses from all soils across England and Wales 1978-2003Nature43724524810.1038/nature0403816148931Search in Google Scholar
BILLETT M.F., CHARMAN D. J., CLARK J.M., EVANS C.D., EVANS M.G , OSTLE N.J., WORRALL F., BURDEN A., DINSMORE K.J., JONES T., McNAMARA N.P., PARRY L., ROWSON J.G., ROSE R. 2010. Carbon balance of UK peatlands: current state of knowledge and future research challenges. CLIMATE RESEARCH Clim Res Vol. 45: 13–29, Contribution to CR Special 24 ‘Climate change and the British Uplands’BILLETTM.F.CHARMAND. J.CLARKJ.M.EVANSC.D.EVANS MGOSTLEN.J.WORRALLF.BURDENA.DINSMOREK.J.JONEST.McNAMARAN.P.PARRYL.ROWSONJ.G.ROSER.2010Carbon balance of UK peatlands: current state of knowledge and future research challengesCLIMATE RESEARCH Clim Res Vol451329Contribution to CR Special 24 ‘Climate change and the British Uplands’10.3354/cr00903Search in Google Scholar
CALLESEN I., RAULUND-RASMUSSEN K., WESTMAN C.J., TAU-STRAND L. 2007. Nitrogen pools and C:N ratios in well-drained Nordic forest soils related to climate and soil texture. Boreal Environ Res 12: 681-692CALLESENI.RAULUND-RASMUSSENK.WESTMANC.J.TAU-STRANDL.2007Nitrogen pools and C:N ratios in well-drained Nordic forest soils related to climate and soil textureBoreal Environ Res12681692Search in Google Scholar
CAO L., SONG J., WANG Q., LI X., YUAN H., LI N., DUAN L. 2017. Characterization of labile organic carbon in different coastal wetland soils of Laizhou Bay, Bohai Sea. Wetlands 37: 163-175CAOL.SONGJ.WANGQ.LIX.YUANH.LIN.DUANL.2017Characterization of labile organic carbon in different coastal wetland soils of Laizhou Bay, Bohai SeaWetlands3716317510.1007/s13157-016-0858-0Search in Google Scholar
CHAPMAN S.J., BELL J., DONNELLY D., LILLY A. 2009. Carbon stocks in Scottish peatlands. Soil Use Manage 25: 105-112CHAPMANS.J.BELLJ.DONNELLYD.LILLYA.2009Carbon stocks in Scottish peatlandsSoil Use Manage2510511210.1111/j.1475-2743.2009.00219.xSearch in Google Scholar
Fourth National Communication under the UN FCCC Fourth National Communications and Reports Demonstrating Progress under the Kyoto Protocol - Annex I https:// unfccc.int/processFourth National Communication under the UN FCCC Fourth National Communications and Reports Demonstrating Progress under the Kyoto Protocol - Annex I https:// unfccc.int/processSearch in Google Scholar
FORTUNIAK K., PAWLAK W., BEDNORZ L., GRYGORUK M., SIEDLECKI M., ZIELIŃSKI M. 2017. Methane and carbon dioxide fluxes of a temperate mire in Central Europe. Agricultural and Forest Meteorology 232: 306-318FORTUNIAKK.PAWLAKW.BEDNORZL.GRYGORUKM.SIEDLECKIM.ZIELIŃSKIM.2017Methane and carbon dioxide fluxes of a temperate mire in Central EuropeAgricultural and Forest Meteorology23230631810.1016/j.agrformet.2016.08.023Search in Google Scholar
GRYGORUK M., BIEREŻNOJ-BAZILLE U., MAZGAJSKI M., SIENKIEWICZ J. 2014. Climate-induced challenges for wetlands: revealing the background for the adaptive ecosystem management in the Biebrza Valley, Poland. In: Rannow S and Neubert M (eds) Managing protected areas in Central and Eastern Europe under climate change. Adv Glob Change Res 58: 209-232GRYGORUKM.BIEREŻNOJ-BAZILLEU.MAZGAJSKIM.SIENKIEWICZJ.2014Climate-induced challenges for wetlands: revealing the background for the adaptive ecosystem management in the Biebrza Valley, PolandRannowSNeubertM(eds)Managing protected areas in Central and Eastern Europe under climate change. Adv Glob Change Res5820923210.1007/978-94-007-7960-0_14Search in Google Scholar
GÜSEWELL S. 2005. High nitrogen:phosphorus ratios reduce nutrient retention and second-year growth of wetland sedges. New Phytol 166: 537-550GÜSEWELLS.2005High nitrogen:phosphorus ratios reduce nutrient retention and second-year growth of wetland sedgesNew Phytol16653755010.1111/j.1469-8137.2005.01320.x15819916Search in Google Scholar
HANEY R.L., FRANZLUEBBERS A.J., JIN V.L., JOHNSON M.V., HANEY E.B., WHITE M.J., HARMEL R.D. 2012. Soil Organic C:N vs. Water-Extractable Organic C:N. Open J Soil Sci 2: 269-274HANEYR.L.FRANZLUEBBERSA.J.JINV.L.JOHNSONM.V.HANEYE.B.WHITEM.J.HARMELR.D.2012Soil Organic C:N vs. Water-Extractable Organic C:N. Open J Soil Sci226927410.4236/ojss.2012.23032Search in Google Scholar
IVITS E., CHERLET M., MEHL W., SOMMER S. 2013. Ecosystem functional units characterized by satellite observed phenology and productivity gradients: A case study for Europe. Ecol Indic 27, 17-28IVITSE.CHERLETM.MEHLW.SOMMERS.2013Ecosystem functional units characterized by satellite observed phenology and productivity gradients: A case study for EuropeEcol Indic27172810.1016/j.ecolind.2012.11.010Search in Google Scholar
JOOSTEN H., CLARKE D. 2002. Wise use of mires and peatlands. Background and principles including a framework for decision-making. International Mire Conservation Group and International Peat Society, Finland, 1-304JOOSTENH.CLARKED.2002Wise use of mires and peatlandsBackground and principles including a framework for decision-making. International Mire Conservation Group and International Peat SocietyFinland1304Search in Google Scholar
JOOSTEN H. 2010. The Global Peatland CO2 Picture. Peatland status and drainage related emissions in all countries of the world. Wetlands International, GreifswaldJOOSTENH.2010The Global Peatland CO2 PicturePeatland status and drainage related emissions in all countries of the world. Wetlands InternationalGreifswaldSearch in Google Scholar
KALBITZ K., GEYER S. 2002. Different effects of peat degradation on dissolved organic carbon and nitrogen. Org Geochem 33: 319–326KALBITZK.GEYERS.2002Different effects of peat degradation on dissolved organic carbon and nitrogenOrg Geochem3331932610.1016/S0146-6380(01)00163-2Search in Google Scholar
KANE E.S., CHIVERS M.R., TURETSKY M.R., TREAT C.C., PETERSEN D.G., WALDROP M., HARDEN J.W., McGUIRE A.D. 2013. Response of anaerobic carbon cycling to water table manipulation in an Alaskan rich fen. Soil Biol Biochem 58: 5060KANEE.S.CHIVERSM.R.TURETSKYM.R.TREATC.C.PETERSEND.G.WALDROPM.HARDENJ.W.McGUIREA.D.2013Response of anaerobic carbon cycling to water table manipulation in an Alaskan rich fenSoil Biol Biochem58506010.1016/j.soilbio.2012.10.032Search in Google Scholar
KNOEPP J.D., COLEMAN D.C., CROSSLEY D.A., CLARK J.S. 2000. Biological indices of soil quality: an ecosystem case study of their use. Forest Ecol Manag 138: 357-368KNOEPPJ.D.COLEMAND.C.CROSSLEYD.A.CLARKJ.S.2000Biological indices of soil quality: an ecosystem case study of their useForest Ecol Manag13835736810.1016/S0378-1127(00)00424-2Search in Google Scholar
KRÜGER J.P., LEIFELD J., GLATZEL S., SZIDAT S., ALEWALL C. 2015. Biogeochemical indicators of peatland degradation – a case study of a temperate bog in northern Germany. Biogeosciences 12, 2861-2871 https://doi.org/10.5194/bg-12-2861-2015KRÜGERJ.P.LEIFELDJ.GLATZELS.SZIDATS.ALEWALLC.2015Biogeochemical indicators of peatland degradation – a case study of a temperate bog in northern GermanyBiogeosciences1228612871https://doi.org/10.5194/bg-12-2861-201510.5194/bg-12-2861-2015Search in Google Scholar
LANE R.R., MACK S.K., DAY J.W., DeLAUNE R.D., MADISON M.J., PRECHT P.R. 2016. Fate of soil organic carbon during wetland loss. Wetlands 36: 1167-1181LANER.R.MACKS.K.DAYJ.W.DeLAUNER.D.MADISONM.J.PRECHTP.R.2016Fate of soil organic carbon during wetland lossWetlands361167118110.1007/s13157-016-0834-8Search in Google Scholar
LISZEWSKA M. 2011. Climate of the Biebrza catchment in 1951-2100. Non published expertise under the Project EU INTERREG IV B CENTRAL EUROPE HABIT CHANGE (2CE 168P3) http://www.habit-change.euLISZEWSKAM.2011Climate of the Biebrza catchment in 1951-2100Non published expertise under the Project EU INTERREG IV B CENTRAL EUROPE HABIT CHANGE (2CE 168P3)http://www.habit-change.euSearch in Google Scholar
LIU Y., JIANG M., LU X., LOU Y., LIU B. 2017. Carbon, nitrogen and phosphorus contents of wetland soils in relation to environment factors in Northeast China. Wetlands 37: 153-161LIUY.JIANGM.LUX.LOUY.LIUB.2017Carbon, nitrogen and phosphorus contents of wetland soils in relation to environment factors in Northeast ChinaWetlands3715316110.1007/s13157-016-0856-2Search in Google Scholar
LUAN J., CUI L., XIANG Ch., WU J., SONG H., MA O. 2014. Soil carbon stocks and quality across intact and degraded alpine wetlands in Zoige, east Qinghai-Tibet Plateau Hongtao Song. Wetl Ecol Manag 22:427–438 http://doi.org/10.1007/s11273-014-9344-8LUANJ.CUIL.XIANGCh.WUJ.SONGH.MAO.2014Soil carbon stocks and quality across intact and degraded alpine wetlands in Zoige, east Qinghai-Tibet Plateau Hongtao SongWetl Ecol Manag22427438http://doi.org/10.1007/s11273-014-9344-810.1007/s11273-014-9344-8Search in Google Scholar
LÜTZOW von M., KÖGEL-KNABER I. 2009. Temperature sensitivity of soil organic matter decomposition – what do we know? Biol Fert Soils 46: 1-15LÜTZOW vonM.KÖGEL-KNABERI.2009Temperature sensitivity of soil organic matter decomposition – what do we know?Biol Fert Soils4611510.1007/s00374-009-0413-8Search in Google Scholar
NAVE L.E., VANCE E.D., SWANSTON C.W., CURTIS P.S. 2009. Impacts of elevated N inputs on north temperature forest soil C storage, C/N, and net N-mineralization, Geoderma 153: 321-240NAVEL.E.VANCEE.D.SWANSTONC.W.CURTISP.S.2009Impacts of elevated N inputs on north temperature forest soil C storage, C/N, and net N-mineralization, Geoderma15332124010.1016/j.geoderma.2009.08.012Search in Google Scholar
NILSSON M., SAGERFORS J., BUFFAM I., LAUDON H. and OTHERS 2008. Contemporary carbon accumulation in a boreal oligotrophic minerogenic mire: a significant sink after accounting for all C-fluxes. Global Change Biol. 14: 2317–2332NILSSONM.SAGERFORSJ.BUFFAMI.LAUDONH.and OTHERS2008Contemporary carbon accumulation in a boreal oligotrophic minerogenic mire: a significant sink after accounting for all C-fluxesGlobal Change Biol142317233210.1111/j.1365-2486.2008.01654.xSearch in Google Scholar
OKRUSZKO H., BYCZKOWSKI A. 1996. Draining of wetlands in the Middle Biebrza Basin in a historical perspective. Zesz Probl Post Nauk Roln 432: 33-43 (in Polish)OKRUSZKOH.BYCZKOWSKIA.1996Draining of wetlands in the Middle Biebrza Basin in a historical perspectiveZesz Probl Post Nauk Roln4323343(in Polish)Search in Google Scholar
OLDE VENTERINK H., KARDEL I., KOTOWSKI W., PEETERS W., WASSEN M.J. 2009. Long-term effects of drainage and hay–removal on nutrient dynamics and limitation in the Biebrza mires, Poland. Biogeochemistry 93: 235-252OLDE VENTERINKH.KARDELI.KOTOWSKIW.PEETERSW.WASSENM.J.2009Long-term effects of drainage and hay–removal on nutrient dynamics and limitation in the Biebrza mires, PolandBiogeochemistry9323525210.1007/s10533-009-9300-5Search in Google Scholar
OSTROWSKA A., PORĘBSKA G. 2014. Assessment of the C/N ratio as an indicator of the decomposability of organic matter in forest soils. Ecol Indic 49: 104-109OSTROWSKAA.PORĘBSKAG.2014Assessment of the C/N ratio as an indicator of the decomposability of organic matter in forest soilsEcol Indic4910410910.1016/j.ecolind.2014.09.044Search in Google Scholar
PIŃEIRO G., OESTERHELD M., BATISTA W.B., PARUELO J.M. 2006. Opposite changes of whole-soil vs. pools C:N ratios: a case of Simpson’s paradox with implications on nitrogen cycling. Global Change Biol 12: 804-809PIŃEIROG.OESTERHELDM.BATISTAW.B.PARUELOJ.M.2006Opposite changes of whole-soil vs. pools C:N ratios: a case of Simpson’s paradox with implications on nitrogen cyclingGlobal Change Biol1280480910.1111/j.1365-2486.2006.01139.xSearch in Google Scholar
RASHFORD B.S., ADAMS R.M., WU J.J., VOLDSETH R.A., GUNTENSPERGEN G.R., WERNER B., JOHNSON W.C. 2016. Impacts of climate change on land-use and wetland productivity in the Prairie Pothole Region of North America Springer-Verlag Berlin Heidelberg (outside the USA), Reg Environ Change 16: 515–526, https://doi.org/10.1007/s10113-015-0768-3RASHFORDB.S.ADAMSR.M.WUJ.J.VOLDSETHR.A.GUNTENSPERGENG.R.WERNERB.JOHNSONW.C.2016Impacts of climate change on land-use and wetland productivity in the Prairie Pothole Region of North America Springer-Verlag Berlin Heidelberg (outside the USA), Reg Environ Change16515526https://doi.org/10.1007/s10113-015-0768-310.1007/s10113-015-0768-3Search in Google Scholar
SIENKIEWICZ J., OSTROWSKA A., VOHLAND K., STRATMANN L., GRYGORUK M. 2014. Indicators for monitoring climate change–induced effects on habitats – a wetland perspective. In: Rannow S and Neubert M (eds) Managing protected areas in Central and Eastern Europe under climate change. Adv Glob Change Res 58: 77- 94SIENKIEWICZJ.OSTROWSKAA.VOHLANDK.STRATMANNL.GRYGORUKM.2014Indicators for monitoring climate change–induced effects on habitats – a wetland perspectiveRannowSNeubertM(eds)Managing protected areas in Central and Eastern Europe under climate change. Adv Glob Change Res58779410.1007/978-94-007-7960-0_6Search in Google Scholar
SMITH P., CHAPMAN S., SCOTT W., BLACK H., WATTENBACH M., MILNE R., CAMPBELL C., LILLY A., OSTLE N., LEVY P.E., LUMSDON D.G., MILLARD P., TOWERS W., ZAEHLE S., SMITH J.U. 2007. Climate change cannot be entirely responsible for soil carbon loss observed in England and Wales 1978-2003. Global Change Biol 13 (12): 2605-2609SMITHP.CHAPMANS.SCOTTW.BLACKH.WATTENBACHM.MILNER.CAMPBELLC.LILLYA.OSTLEN.LEVYP.E.LUMSDOND.G.MILLARDP.TOWERSW.ZAEHLES.SMITHJ.U.2007Climate change cannot be entirely responsible for soil carbon loss observed in England and Wales 1978-2003Global Change Biol13122605260910.1111/j.1365-2486.2007.01458.xSearch in Google Scholar
SPRINGOB G., KIRCHMANN H. 2003. Bulk soil C to N ratio as a simple measure of net N mineralization from stabilized soil organic matter in sandy arable soils. Soil Biol Biochem 35: 629-632SPRINGOBG.KIRCHMANNH.2003Bulk soil C to N ratio as a simple measure of net N mineralization from stabilized soil organic matter in sandy arable soilsSoil Biol Biochem3562963210.1016/S0038-0717(03)00052-XSearch in Google Scholar
TVEIT A., SCHWACKE R., SVENNING M.M., URICH T. 2013. Organic carbon transformations in high-Arctic peat soils: key functions and microorganisms. The ISME Journal 7: 299–311, https://doi.org/10.1038/ismej.2012.99TVEITA.SCHWACKER.SVENNINGM.M.URICHT.2013Organic carbon transformations in high-Arctic peat soils: key functions and microorganismsThe ISME Journal7299311https://doi.org/10.1038/ismej.2012.9910.1038/ismej.2012.99355441522955232Search in Google Scholar
VAN LOON A.H., SCHOT P.P., BIERKENS M.F.P., BATELAAN O., WASSEN M.J. 2009. Throughflow as a determining factor for habitat contiguity in a near natural fen (Biebrza valley). J Hydrol 379: 30-40VAN LOONA.H.SCHOTP.P.BIERKENSM.F.P.BATELAANO.WASSENM.J.2009Throughflow as a determining factor for habitat contiguity in a near natural fen (Biebrza valley)J Hydrol379304010.1016/j.jhydrol.2009.09.041Search in Google Scholar
WANG J., BAI J., ZHAO Q., LU Q., XIA Z. 2016. Five-year changes in soil organic carbon and total nitrogen in coastal wetlands affected by flow-sediment regulation in a Chinese delta. Sci Rep 6-21137, https://doi.org10.1038/srep21137WANGJ.BAIJ.ZHAOQ.LUQ.XIAZ.2016Five-year changes in soil organic carbon and total nitrogen in coastal wetlands affected by flow-sediment regulation in a Chinese deltaSci Rep 6-21137https://doi.org10.1038/srep2113710.1038/srep21137475476226879008Search in Google Scholar
WASSEN M.J., BARENDREGT A., PAŁCZYŃSKI A., DE SMIDT J.T., DE MARS H. 1990. The relationship between fen vegetation gradients, groundwater flow and flooding in an undrained valley mire at Biebrza, Poland. J Ecol 78: 1106-1122WASSENM.J.BARENDREGTA.PAŁCZYŃSKIA.DE SMIDTJ.T.DE MARSH.1990The relationship between fen vegetation gradients, groundwater flow and flooding in an undrained valley mire at Biebrza, PolandJ Ecol781106112210.2307/2260955Search in Google Scholar
WASSEN M.J., OLDE VENTERINK H.G.M., DE SWART E.O.A.M. 1994. Water sources and water chemistry as a conditioning factor for nutrient availability in the Biebrza fens. In: Okruszko H, Wassen MJ (eds) Towards protection and sustainable use of the Biebrza Wetlands: Exchange and integration of research results for the benefit of a Polish–Dutch Joint Research Plan 2: 83-102WASSENM.J.OLDE VENTERINKH.G.M.DE SWARTE.O.A.M.1994Water sources and water chemistry as a conditioning factor for nutrient availability in the Biebrza fensIn: Okruszko H, Wassen MJ (eds) Towards protection and sustainable use of the Biebrza Wetlands: Exchange and integration of research results for the benefit of a Polish–Dutch Joint Research Plan283102Search in Google Scholar
WASSEN M.J., PETERS W.H.M., OLDE VENTERINK H. 2002. Patterns in vegetation, hydrology and nutrient availability in an undisturbed river floodplain in Poland. Plant Ecol 165: 27-43WASSENM.J.PETERSW.H.M.OLDE VENTERINKH.2002Patterns in vegetation, hydrology and nutrient availability in an undisturbed river floodplain in PolandPlant Ecol165274310.1023/A:1021493327180Search in Google Scholar
WATT M.S., PALMER D.J. 2012. Use of regression kriging to develop a Carbon:Nitrogen ratio surface for New Zealand. Geoderma 183-184: 49-57WATTM.S.PALMERD.J.2012Use of regression kriging to develop a Carbon:Nitrogen ratio surface for New ZealandGeoderma183-184495710.1016/j.geoderma.2012.03.013Search in Google Scholar
WEEDON J.T., KOWALCHUK G.A., AERTS R., VAN HAL J.R., VAN LOGTESTIJN R., TAŞ N., RÖLING W.F., VAN BODEGOM P.M. 2012. Summer warming accelerates sub-arctic peatland nitrogen cycling without changing enzyme pools or microbial community structure. Global Change Biol 18: 138150WEEDONJ.T.KOWALCHUKG.A.AERTSR.VAN HALJ.R.VAN LOGTESTIJNR.TAŞN.RÖLINGW.F.VAN BODEGOMP.M.2012Summer warming accelerates sub-arctic peatland nitrogen cycling without changing enzyme pools or microbial community structureGlobal Change Biol1813815010.1111/j.1365-2486.2011.02548.xSearch in Google Scholar
WEEDON J.T., AERTS R., KOWALCHUK G.A., VAN LOGTESTIJN R., ANDRINGA D., VAN BODEGOM P.M. 2013. Temperature sensitivity of peatland C and N cycling: Does substrate supply play a role? Soil Biol Biochem 61: 109-120WEEDONJ.T.AERTSR.KOWALCHUKG.A.VAN LOGTESTIJNR.ANDRINGAD.VAN BODEGOMP.M.2013Temperature sensitivity of peatland C and N cycling: Does substrate supply play a role?Soil Biol Biochem6110912010.1016/j.soilbio.2013.02.019Search in Google Scholar
WELLOCK M.L., REIDY B., LAPERLE C.H.M., BOLGER T, KIELY G. 2001. Soil organic carbon stocks of afforested peatlands in Ireland. Forestry 84: 441-451, https://doi.org/10.1093/forestry/cpr046WELLOCKM.L.REIDYB.LAPERLEC.H.M.BOLGERTKIELYG.2001Soil organic carbon stocks of afforested peatlands in IrelandForestry84441451https://doi.org/10.1093/forestry/cpr04610.1093/forestry/cpr046Search in Google Scholar
WRB 2014. World Reference Base for Soil Resources, FAO, RomeWRB2014World Reference Base for Soil ResourcesFAORomeSearch in Google Scholar
