Research Units Forest Soils and Biogeochemistry Research Focus Projects Biogeochemical cycling and ground vegetation Produkte Staff Bachelor / Master

Duration: 1996 -

Nutrient fluxes, nutrient status of the stand and ground vegetation on the LWF sites

Rationale

Fig. 1 - Litterfall, snowfall and rain collectors on the LWF site of Novaggio

The better understanding of the processes driving the dynamics of forest ecosystems requires the documentation of the constantly interacting compartments and fluxes of the biogeochemical cycle. In this project we study two fluxes (deposition of nutrients through precipitation and litterfall) and two compartments (foliage and ground vegetation).

Project aims

The aims of the project are:

• to quantify two important terms of the annual nutrient budget at the stand level (throughfall and litterfall).
• to estimate total atmospheric deposition, and thus monitor the pollution climate the forest ecosystem is subjected to. From the incident precipitation and throughfall data, changes in the precipitation chemistry influenced by the forest canopy (foliar leaching and uptake) can be discriminated and the contribution of wet and dry deposition of certain atmospheric compounds can be inferred.
• to assess the nutrient status of the forest stands (foliar analysis) and detect possible deficiencies or imbalances.
• to assess spatial and temporal variations of the floristic composition of the ground vegetation. Ground vegetation is an important compartment of the ecosystem in terms of biodiversity and it takes an active part in the general functioning of the ecosystem. It is also a useful bio-indicator of the site conditions and its monitoring may enable the detection of environmental changes. This latter aspect is detailed in the description of the project "Nitrogen and ground vegetation".
• to collect data to parameterize, calibrate and validate models for Swiss conditions.
• to assess the risks of development of critical situations, such as exceedances of critical loads.

Methods

The sampling methods are based on the methods recommended in the manuals published by the European ICP programmes (ICP Forests, see References) The sampling design is such that 1) a trade-off is achieved between the representativeness of the estimates and the logistical costs 2) direct comparisons between the various compartments and fluxes (soil, vegetation, litterfall, throughfall) are possible.

Click on Image to enlarge.

Fig. 2 - Fluxes and compartments measured on LWF sites (in red). The wet and dry components of atmospheric deposition are estimated from bulk precipitation and throughfall data using the extended "canopy budget model" described in EC-UNECE (2001).

Precipitation, throughfall and stemflow sampling on LWF sites

Incident precipitation is sampled by 3 funnel-type bulk collectors in an open area, next to a meteorological station also run by LWF. Sites where snow may be important are equipped with a bucket-type snow collector. In the forest stand, throughfall is sampled by 16 collectors identical to those used in the open. Four snow collectors are used on plots where snow precipitation is expected to be abundant.

Fig. 3 - Rainfall collector on the LWF site of Lausanne

Stemflow is sampled with gutter-like collectors coiled in spiral around the stem of 5 individual broadleaved trees, and connected to an automated tipping-bucket system, allowing continuous recording of volumes and sampling of representative proportional fractions. Stemflow is currently measured on one beech stand.

Fig. 4 - Paul Weibel installing a gutter on a tree in Novaggio

Precipitation samples are collected from the field every two weeks and sent or brought to the WSL laboratory. Each sample is prepared in duplicate, one for chemical analysis at the WSL Central Laboratory, a second for storage at -20°C or +2°C until validation of the analyses. Ammonium (NH₄⁺) is determined colorimetrically with automated flow injection analysis (FIA). Calcium (Ca), magnesium (Mg), potassium (K), sodium (Na) and total phosphorus (P) are determined on acidified samples (1.2% HNO3-Suprapur) with induced coupled plasma atomic emission spectrometry (ICP-AES). Nitrate (NO₃^-), sulfate (SO₄^2-) and chloride (Cl^-) are determined with ion chromatography (IC). Total dissolved nitrogen (TDN) had been measured with alkaline persulfate oxidation (converting all nitrogen into nitrate) until the beginning of 2001. Since March 2001 TDN has been analyzed after acidification to pH 2 to 3 with combustion at 720 °C (converting all nitrogen to nitrogen monoxide) and chemiluminescence gas detection using a TOC-V analyser (Shimadzu, Tokyo, Japan).

Litterfall

Litterfall is sampled on 7 plots with 10 collectors emptied monthly (Fig. 5). On plots in the alpine region litterfall sampling is usually interrupted in winter (with the exception of three alpine plots during the winter 2002/2003). In the laboratory the litter samples are oven dried at 65 °C and sorted into leaves or needles of the main species, leaves or needles of other species, twigs/bark with diamater < 1 cm, branches with diameter > 1 cm, fruits of the main species, and rest (lichen, moss, blooms, indefinable parts). The sorted litter samples are then ground and solubilised for chemical analysis. Total C (carbon) and total N (nitrogen) are determined with ion chromatography (IC). Calcium (Ca), magnesium (Mg), potassium (K), sodium (Na), boron (B), aluminium (Al), copper (Cu), iron (Fe), manganese (Mn), nickel (Ni), total phosphorus (P) and total sulphur (S) are determined with induced coupled plasma atomic emission spectrometry (ICP-AES). All chemical analyses are carried out at the WSL Central Laboratory.

Nutrient status (foliar analyses)

Foliage is sampled (by tree climbing) every second year (Fig. 6). Five trees of each main species are sampled in the buffer zone of the LWF plots. After drying at 65 °C the weight of 100 leaves or 1000 needles is determined. The samples are then ground and solubilised for chemical analysis like the litterfall samples.

Fig. 5 - Litterfall collector on the LWF-plot in Visp	Fig. 6 - Foliage sampling on a beech tree on the plot in Othmarsingen

Ground vegetation

• See project "Nitrogen and ground vegetation"

References

• Anonymous, 1993. UN-ECE Convention on Long-Range Transboundary Air Pollution - International Co-operative Programme on Integrated Monitoring on Air Pollution Effects: Manual for integrated monitoring. Programme Phase 1993-1996. Helsinki, Environmental Data Centre (EDC). 114 p.
• Anonymous, 1994. UN-ECE Convention on Long-Range Transboundary Air Pollution - International Co-operative Programme on Assessment and Monitoring of Air Pollution Effects on Forests: Manual on methods and criteria for harmonized sampling, assessment, monitoring and analysis of the effects of air pollution on forests. Hamburg, Prague, Programme Coordinating Centres West and East. 177 p.
• and subsequent revisions of these manuals.
• EC-UN/ECE, de Vries, W., Reinds, G. J., van der Salm, C., Draaijers, G. P. J., Bleeker, A., Erisman, J. W., Auée, J., Gundersen, P., Kristensen, H. L., van Dobben, H., de Zwart, D., Derome, J., Voogd, J. C. H., Vel, E. M., 2001. Intensive monitoring of forest ecosystems in Europe. 2001 technical report. EC, UN/ECE, Brussels, Geneva, 177 p.

Data

Fig. 7 - Estimated total deposition of nitrogen on LWF plots, and range of empirical critical loads for nitrogen. Years of reference range from 1995 to 2007.

Publications

• Search the LWF publications database by network, site, category and year.
  

• Thimonier A., Graf Pannatier E., Schmitt M., Waldner P., Walthert L., Schleppi P., Dobbertin M., Kräuchi N. 2009. Does exceeding the critical loads for nitrogen alter nitrate leaching, the nutrient status of trees and their crown condition at Swiss Long-term Forest Ecosystem Research (LWF) sites? European Journal of Forest Research. doi:10.1007/s10342-009-0328-9.
• Graf Pannatier E., Dobbertin M., Schmitt M., Thimonier A., Waldner P., 2009. L'eau des sols forestiers: un milieu sensible aux changements. Langzeitforschung für eine nachhaltige Waldnutzung. Forum für Wissen 2009: 21-30. [PDF, 1.02 MB]
• Waldner P., Schmitt M., Schaub M., Graf Pannatier E., Thimonier A., 2009. Stickstoffeintrag und Ozonbelastung im Schweizer Wald aus der Sicht der Langfristigen Waldökosystem-Forschung. Langzeitforschung für eine nachhaltige Waldnutzung. Forum für Wissen 2009: 113-124.  [PDF, 1.61 MB]
• Dobbertin M., Schleppi P., Schmitt M., Thimonier A., Waldner P., 2008. Stickstoffeintrag und Kohlenstoffsenke der Wälder - Löst der Stickstoff unser Kohlenstoffproblem? Natur und Mensch 50(6): 17-21.
• Mosello R., Amoriello T., Benham S., Clarke N., Derome J., Derome K., Genouw G., Koenig N., Orrù A., Tartari G., Thimonier A., Ulrich E., Lindroos A.-J., 2008. Validation of chemical analyses of atmospheric deposition on forested sites in Europe: 2. DOC concentration as an estimator of the organic ion charge. Journal of Limnology 67(1): 1-14. PDF [700 kb]
• Thimonier A., Schmitt M., Waldner P., Schleppi P., 2008. Seasonality of the Na/Cl ratio in precipitation and implications of canopy leaching in validating chemical analyses of throughfall samples. Atmospheric Environment 42: 9106-9117. PDF [421 kb]
• Graf Pannatier E., Dobbertin M., Schmitt M., Thimonier A., Waldner P., 2007. Effects of the drought 2003 on forests in Swiss Level II plots. In: J. Eichhorn (Ed.), Forests in a Changing Environment. Results of 20 years ICP Forests Monitoring, Göttingen, Germany, October 25-28, 2006. Schriften aus der Forstlichen Fakultät der Universität Göttingen und der Nordwestdeutschen Forstlichen Versuchsanstalt. Vol. 142, pp. 128-135. PDF [600 kb]
  
• Thimonier A., Schmitt M., Graf Pannatier E., Schaub M., Waldner P., 2007. Atmospheric deposition and ozone levels in Swiss forests: Are critical values exceeded? In: J. Eichhorn (Ed.), Forests in a Changing Environment. Results of 20 years ICP Forests Monitoring, Göttingen, Germany, October 25-28, 2006. Schriften aus der Forstlichen Fakultät der Universität Göttingen und der Nordwestdeutschen Forstlichen Versuchsanstalt. Vol. 142, pp. 164-169. PDF [334 kb]
• Waldner P., Schaub M., Graf Pannatier E., Schmitt M., Thimonier A., Walthert L., 2007. Critical loads of acidity and nitrogen, and critical levels of ozone in Swiss forests. Environmental Monitoring and Assessment 128: 5-17. PDF [330 kb]
• Rogora M., Mosello R., Arisci S., Brizzio M.C., Barbieri A., Balestrini R., Waldner P., Schmitt M., Stähli M., Thimonier A., Kalina M., Puxbaum H., U. Nickus, E. Ulrich, A. Probst, 2006. An overview of atmospheric deposition chemistry over the Alps: present status and long-term trends. Hydrobiologia (Special Issue, A. Lami, A. Boggero (eds), Ecology of high altitude aquatic systems in the Alps). Hydrobiologia 562: 17-40. PDF [636 kb]
• Schmitt, M., Thöni, L., Waldner, P. & Thimonier, A., 2005. Total deposition of nitrogen on Swiss Long-term Ecosystem Research (LWF) plots: in situ evaluation of the throughfall and the inferential method. Atmospheric Environment, Vol. 39 (6): 1079-1091. PDF [287 kb]
• Thimonier A., Schmitt M., Waldner P., Rihm B., 2005. Atmospheric deposition on Swiss Long-term Forest Ecosystem Research (LWF) plots. Environmental Monitoring and Assessment 104: 81-118. PDF [572 kb]
• Dobbertin M., Bernhard L., Graf Pannatier E., Schmitt M., Thimonier A., Walthert L., 2001. Langfristige Waldökosystemforschung in Graubünden. Bündnerwald 54(2): 68-70.
• Thimonier A., Schmitt M., Cherubini P., Kräuchi N., 2001. Monitoring the Swiss forest: building a research platform. In: T. Anfodillo, V. Carraro (eds), Monitoraggio ambientale: metodologie ed applicazioni. Atti del XXXVIII Corso di Cultura in Ecologia, 2001. S. Vito di Cadore, Centro Studi per l'Ambiente Alpino, Università degli Studi di Padova, pp. 121-134. PDF [128 kb]
• Thimonier Rickenmann A., Schmitt M., Brang P., 2000. Zuviel des Guten. Jahresbericht der Eidg. Forschungsanstalt WSL 2000 : 19.
• Thimonier A., 1998. Measurement of atmospheric deposition under forest canopies: some recommendations for equipment and sampling design. Environmental Monitoring and Assessment 53: 353-387. PDF [280 kb]
• Thimonier A., 1998. Variabilité spatio-temporelle des dépôts atmosphériques d´éléments minéraux sous hêtraie. Schweizerische Zeitschrift für Forstwesen (Journal Forestier Suisse) 149(8): 585-614.
• Thimonier A., Dobbertin M., 1998. Langfristige Waldökosystem-Forschung: Erste Ergebnisse. In: P. Brang (Redaktion), Sanasilva-Bericht 1997. Gesundheit und Gefährdung des Schweizer Waldes Ð eine Zwischenbilanz nach 15 Jahren Waldschadenforschung. Berichte der Eidg. Forschungsanstalt für Wald, Schnee und Landschaft, Birmensdorf 345, pp. 59-60.

Participants

Research team	Laboratroy	Former and external collaborators
Maria Schmitt (project leader) Anne Thimonier (project leader) Peter Waldner (project leader) Daniele Pezzotta	Anna Brechbühl Yuk-Ying Cheung-Tang Noureddine Hajjar Oliver Schramm Alois Zürcher Daniel Christen	Peter Kull Daniel Nievergelt

Contact

• Maria Schmitt Oehler
  

• Anne Thimonier Rickenmann
  

• Peter Waldner
  

Links

• International Co-operative Programme on Assessment and Monitoring of Air Pollution Effects on Forests (ICP Forests)
• Co-operative Programme for Monitoring of the Long-Range Transmission of Air Pollutants in Europe (EMEP)
• Federal Office for the Environment (FOEN)
  
• Nationales Beobachtungsnetz für Luftfremdstoffe (NABEL)
• Ammoniak-Immissionsmessungen in der Schweiz (Bericht, PDF, 993 kb)
• Research Group for Environmental Monitoring (FUB)
• Institute for Applied Plant Biology (IAP)

Keywords:

nutrient cycling, atmospheric deposition, throughfall, litterfall, foliar analyses, ground vegetation