Abstract
Nitrogen additions as NH4NO3 corresponding to 0 (N0), 1 (N1), 3 (N3) and 10 (N10) g N m-2 yr-1 were made to Sphagnum magellanicum cores at two-week intervals in situ at four sites across Europe, i.e. Lakkasuo (Finland), Männikjärve (Estonia), Moidach More (UK) and Côte de Braveix (France). The same treatments were applied in a glasshouse experiment in Neuchâtel (Switzerland) in which the water table depth was artificially maintained at 7, 17 and 37 cm below the moss surface. In the field, N assimilation in excess of values in wet deposition occurred in the absence of growth, but varied widely between sites, being absent in Lakkasuo (moss N:P ratio 68) and greatest in Moidach More (N:P 21). In the glasshouse, growth was reduced by lowering the water table without any apparent effect on N assimilation. Total N content of the moss in field sites increased as the mean depth of water table increased indicating growth limitation leading to increased N concentrations which could reduce the capacity for N retention. Greater contents of NH4+ in the underlying peat at 30 cm depth, both in response to NH4NO3 addition and in the unamended cores confirmed poor retention of inorganic N by the moss at Lakkasuo. Nitrate contents in the profiles at Lakkasuo, Moidach More, and Côte de Braveix were extremely low, even in the N10 treatment, but in Männikjärve, where the mean depth of water table was greatest and retention absent, appreciable amounts of NO3- were detected in all cores. It is concluded that peatland drainage would reduce the capture of inorganic N in atmospheric deposition by Sphagnum mosses.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aerts R, Wallén B & Malmer N (1992) Growth-limiting nutrients in Sphagnum-dominated bogs subject to low and high atmospheric nitrogen supply. J. Ecol. 80: 131-140
Baxter R, Emes MJ & Lee JA (1992) Effects of an experimentally applied increase in ammonium on growth and amino-acid metabolism of Sphagnum cuspidatum Ehrh. ex. Hoffm. from differently polluted areas. New Phytol. 120: 265-274
Bremner JM (1965) Inorganic forms of nitrogen. In: Black CA (Ed) Methods of Soil Analysis, Part 2 (pp 1179-1206). American Society of Agronomy, Madison, Wisconsin, USA
Clymo RS (1973) The growth of Sphagnum: some effects of environment. J. Ecol. 61: 849-869
Clymo RS (1970) The growth of Sphagnum: methods of measurement. J. Ecol. 58: 13-49
Crill P, Martikainen PJ, Nykänen H & Silvola J (1994) Temperature and N fertilization effects on methane oxidation in a drained peatland soil. Soil Biol. Biochem. 26: 1331-1340
Crooke WM & Simpson WE (1971) Determination of ammonium in Kjeldahl digests of crops by an automated procedure. J. Sci. Fd Agric. 22: 9-10
Gerendas J, Heeschen V, Kahl S, Ratcliffe RG & Rudolph H (1997) An investigation of N metabolism and pH regulation in Sphagnum using in vivo nuclear magnetic resonance and stable isotope mass spectrometry. Isotopes in Environ. and Health Stud. 33: 21-29
Grosvernier Ph, Matthey Y & Buttler A (1997) Growth potential of three Sphagnum species in relation to water table level and peat properties with implications for their restoration in cut-over bogs. J. Appl. Ecol. 34: 471-483
Hemond HF (1983) The nitrogen budget of Thoreau's bog. Ecology 64: 99-109
Henriksen A & Selmer-Olsen AR (1970) Automatic methods for determining nitrate and nitrite in water and soil extracts. Analyst 95: 514-518
INDITE (1994) Impacts of Nitrogen Deposition in Terrestrial Ecosystems. Report of the United Kingdom Review Group on Impacts of Atmospheric Nitrogen. Department of the Environment, London, 110 pp.
Matthey W (1971) Ecologie des insectes aquatiques d'une tourbière du Haut-Jura. Revue Suisse de Zoologie, Ann. Soc. Suisse Zool. et du Muséum d'Hist. Natur. Genève 78: 367-536
Murphy J & Riley JP (1962) A modified single solution method for the determination of phosphate in natural waters. Anal. Chim. Acta 27: 31-36
Neuhäusl R (1975) Hochmoore am Teich Velké Darko. Vegetace CSSR, A9, 267 pp. Academia, Praha.
Regina K, Nykänen H, Silvola J & Martikainen, PJ (1996) Fluxes of nitrous oxide from boreal peatlands as affected by peatland type, water table level and nitrification capacity. Biogeochem. 35: 401-418
Silcock DJ & Williams BL (1995) The fate and effects of inorganic nitrogen inputs to raised bog vegetation. In: Jenkins A, Ferrier RC & Kirby C (Eds) (pp 44-48). Ecosystem Manipulation Experiments. Ecosystems Research Report 20. EC Brussels
Von Post L (1929) Sveriges Geologiska Undersøkning torvinventering och nogra av dess hittils vunna resultat. Svenska Moss Kulturforeningens Tids. 36: 296-308
Wall LL, Gehrke CW, Neuner TE, Cathey RD & Rexroad PR (1975) Total protein nitrogen: evaluation and comparison of four different methods. J. Assocn Off. Agric. Chem. 58: 807-811
Williams BL & Silcock DJ (1997) Nutrient and microbial changes in the peat profile beneath Sphagnum magellanicum in response to additions of ammonium nitrate. J. Appl. Ecol. 34: 961-970
Williams BL Silcock DJ & Young ME (1998) Nitrogen phosphorus interactions in peat. Ecologie (In press)
Williams BL & Wheatley, RE (1988) Nitrogen mineralization and water-table height in oligotrophic deep peat. Biol. Fertil Soils 6: 141-147
Woodin, SJ & Lee JA (1987) The fate of some components of acidic deposition in ombrotrophic mires. Environ. Pollut 45: 61-72
Woodin S, Press MC & Lee JA (1985) Nitrate reductase activity in Sphagnum fuscum in relation to wet deposition of nitrate from the atmosphere. New Phytol. 99: 381-388
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Williams, B., Buttler, A., Grosvernier, P. et al. The fate of NH4NO3 added to Sphagnum magellanicum carpets at five European mire sites. Biogeochemistry 45, 73–93 (1999). https://doi.org/10.1023/A:1006133828518
Issue Date:
DOI: https://doi.org/10.1023/A:1006133828518