Modelling above and below ground carbon dynamics in a mixed beech and spruce stand influenced by climate (original) (raw)

References

• Ayres MP, Lombardero MJ (2000) Assessing the consequences of global change for forest disturbance from herbivores and pathogens. Sci Total Environ 262:263–286
  Article PubMed CAS Google Scholar
• Barr AG, Griffis TJ, Black TA, Lee X, Staebler RM, Fuentes JD, Chen Z, Morgenstern K (2002) Comparing the carbon budgets of boreal and temperate deciduous forest stands. Can J For Res 32:813–822
  Article Google Scholar
• Black TA, Hogg EH, Griffis TJ, Morgenstern K, Klujn N, Theede A, Nesic Z (2007) Climatic controls on the carbon and water balances of a boreal aspen forest, 1994–2003. Glob Change Biol 13:561–576
  Article Google Scholar
• BayFORKLIM (1996) Klimaatlas von Bayern. Buchhandlung Kanzler, München
• Bolte A, Rahmann T, Kuhr M, Pogoda P, Murach D, von Gadow K (2004) Relationships between tree dimension and coarse root biomass in mixed stands of European beech (Fagus sylvatica L.) and Norway spruce (Picea abies [L.] Karst.). Plant Soil 264:1–11
  Article CAS Google Scholar
• Coops C, Waring RH (2001) Assessing forest growth across southwestern Oregon under a range of current and future global change scenarios using a processmodel, 3-PGN. Glob Change Biol 7:15–29
  Article Google Scholar
• Fehrman L, Kuhr M, von Gadow K (2003) Zur Analyse der Grobwurzelsysteme großer Waldbäume an Fichte [Picea abies (L.) Karst.] und Buche [Fagus sylvatica L.]. Forstarchiv 74:96–102
  Google Scholar
• Drew MC (1987) Function of root tissues in nutrient and water transport. In: Gregory PJ, Lake JV, Rose DA (eds) Root development and function. Cambridge University Press, Cambridge, pp 71–101
  Google Scholar
• Glynn C, Herms DA, Orians CM, Hansen RC, Larsson S (2007) Testing the growth-differentiation balance hypothesis: dynamic responses of willows to nutrient availability. New Phytol. doi:10.1111/j.1469-8137.2007.02203.x
• Grote R (1998) Integrating dynamic morphological properties into forest growth modelling. II. Allocation and mortality. For Ecol Manage 111(2/3):193–210
  Article Google Scholar
• Grote R (2002) Foliage and branch biomass estimation of coniferous and deciduous tree species. Silva Fenn 36(4):779–788
  Google Scholar
• Grote R, Pretzsch H (2002) A model for individual tree development based on physiological processes. Plant Biol 4:167–180
  Article Google Scholar
• Haxeltine A, Prentice IC (1996) A general model for the light use efficiency of primary production by terrestrial ecosystems. Funct Ecol 10:551–561
  Article Google Scholar
• CC IP (2001) Land, use, land use change and forestry. In: Watson RT, Noble IR, Bolin B, Ravindranath NH, Verardo DJ, Docken DJ (eds) IPCC special report. Cambridge University Press, Cambridge, p 337
  Google Scholar
• IPCC (2007) IPCC WGI Fourth assessment report to climate change: The physical science basis; summary for policymakers. IPCC Secretariat, Geneva, Switzerland, p 18
• Jacob D, Andrae U, Elgered G, Fortelius C, Graham LP, Jackson SD, Karstens U, Koepken C, Lindau R, Podzun R, Rockel B, Rubel F, Sass HB, Smith RND, Van den Hurk BJJM, Yang X (2001) A comprehensive model intercomparison study investigating the water budget during the BALTEX-PIDCAP period. Meteorol Atmos Phys 77(1–4):19–43
  Article Google Scholar
• KLIWA (2006) Regionale Klimaszenarien für Süddeutschland. KLIWA-Berichte 9, p 102
• Jonas M, Staeger T, Schönwiese CD (2005) Berechnung der Wahrscheinlichkeiten für das Eintreten von Extremereignissen durch Klimaänderungen–Schwerpunkt Deutschland -. UBA- Bericht 201 41 254, Dessau, p 252
• Malanson GP (1993) Comment on modelling ecological response to climatic change. Clim Change 23:95–109
  Article Google Scholar
• Mäkela A (1990) Modelling structural-functional relationships in whole-tree growth: Resource allocation. In: Dixon RK, Meldahl RS, Ruark GA, Warren WG (eds) Process modelling of forest growth responses to environmental stress. Timber Press, Portland, pp 81–95
  Google Scholar
• Meehl GA, David TK, Easterling R, Changnon S, Pielke R Jr, Changnon D, Evans J, Groisman P, Knutson TR, Kunkel KE, Mearns LO, Parmesan C, Pulwarty R, Root I, Richard T, Sylves T, Whetton P, Zwiers F (2000) An Introduction to Trends in Extreme Weather and Climate Events: Observations, Socioeconomic Impacts, Terrestrial Ecological Impacts, and Model Projections. Bull Am Meteorol Soc 81(3):413–416
  Article Google Scholar
• Monteith JL (1965) Evaporation and environment. In: Fogg GE (ed) The state and movement of water in living organisms, Sym Soc Exp Biol, vol 19. Academic Press, New York, pp 205–234
  Google Scholar
• Mund M, Kummetz E, Hein M, Bauer GA, Schulze ED (2002) Growth and carbon stocks of a spruce forest chronosequence in central Europe. For Ecol Manage 171:275–296
  Article Google Scholar
• Nikolova P, Raspe S, Andersen CP, Mainiero R, Blaschke H, Matyssek R, Häberle KH (2008a) Effects of the extreme drought in 2003 on soil respiration in mixed forest. Eur J For Res. doi:10.1007/s10342-008-0218-6
• Nikolova P, Blaschke H, Matyssek R, Pretzsch H, Seifert T (2008b) Combined application of computer tomography and light microscopy for analysis of conductive xylem area in coarse roots of European beech and Norway spruce. Eur J For Res. doi:10.1007/s10342-008-0211-0
• Oleksyn J, Reich PB, Chalupka W, Joelker GT (1999) Differential above- and below-ground biomass accumulation of European Pinus sylvestris populations in a 12-year-old provenance experiment. Scand J For Res 14(1):7–17
  Google Scholar
• Penning de Vries FWT, Jansen DM, ten Berge HFM, Bakema A (1989) Simulation of ecophysiological processes of growth in several annual crops. Simulation Monographs 29. PUDOC, Wageningen, The Netherlands
• Polomski J, Kuhn N (1998) Wurzelsysteme. Eidgenössische Forschungsanstalt für Wald, Schnee und Landschaft, Birmensdorf (eds) Haupt, Bern, Stuttgart, Wien, p 290
• Pretzsch H (1992) Modellierung der Kronenkonkurrenz von Fichte und Buche in Rein- und Mischbeständen. Allgem Forst- u Jagdztg 163(11/12):203–213
  Google Scholar
• Pretzsch H (1996) Growth trends of forests in southern Germany. In: Spiecker H, Miellkäinen K, Köhl M, Skovsgard JP (eds) Growth trends in European forests: studies from 12 countries. Springer, Berlin, pp 107–131
  Google Scholar
• Pretzsch H (1999) Changes in forest growth. Forstw Cbl 118(4):228–250
  Article Google Scholar
• Pretzsch H, Kahn M, Grote R (1998) Die Fichten-Buchen-Mischbestände des Sonderforschungsbereiches Wachstum oder Parasitenabwehr? im Kranzberger Forst Forstw Cbl 117:241–257
  Article Google Scholar
• Pretzsch H, Dursky J (2002) Growth reaction of Norway spruce (Picea abies (L.) Karst.) and European beech (Fagus silvatica L.) to possible climatic changes in Germany. A sensitivity study. Forstw Cbl 121:145–154
  Article Google Scholar
• Price DT, Apps MJ (1995) The boreal forest transect case study: global change effects on ecosystem processes and carbon dynamics in boreal Canada. Water Air Soil Pollut 82:203–214
  Article CAS Google Scholar
• Roloff A, Römer HP (1989) Beziehungen zwischen Krone und Wurzel bei der Rotbuche (Fagus sylvatica L.). Allgem Forst- u Jagdztg 160(9/10):200–205
  Google Scholar
• Rötzer T (2003) Modellierung der Baumkronenentwicklung mittels eines ökophysiologi-schen Prozessmodells. Bundesministerium für Verbraucherschutz, Ernährung und Land-wirtschaft Ref. 533, Bonn:73-42
• Rötzer T, Grote R, Pretzsch H (2004) The timing of bud burst and its effect on tree growth. Int J Biometeorol 48:109–118
  Article PubMed Google Scholar
• Rötzer T, Grote R, Pretzsch H (2005) Effects of environmental changes on the vitality of forest stands. Eur J For Res 124:349–362
  Google Scholar
• Seifert T (2007) Simulating the extent of decay caused by Heterobasidion annosum s.l. in stems of Norway spruce. For Ecol Manag. doi:10.1016/j.foreco.2007.02.036
• Seifert T, Müller-Starck G (2008) Impacts of fructification on biomass production and correlated genetic effects in Norway spruce (Picea abies [L.] Karst.). Eur J For Res. doi:10.1007/s10342-008-0211-0
• Skovsgaard JP, Stupa I, Vesterdal L (2006) Distribution of biomass and carbon in even-aged stands of Norway spruce (Picea abies (L.) Karst.): A case study on spacing and thinning effects in northern Denmark. Scand J For Res 21:470–488
  Article Google Scholar
• UBA (2007) Neue Ergebnisse zu regionalen Klimaänderungen. Hintergrundpapier Neue Ergebnisse zu regionalen Klimaänderungen http://www.umweltbundesamt.de/uba-info-presse/hintergrund/Regionale-Klimaaenderungen.pdf, Umweltbundesamt Dessau, p 27
• Valentine HT (1985) Tree-growth models: derivations employing the pipe-model theory. J Theor Biol 117:579–585
  Article Google Scholar
• Wang JR, Letchford T, Comeau P, Kimmins JP (2000) Above- and below-ground biomass and nutrient distribution of a paper birch and subalpine mixed-species stand in the Sub-Boreal Spruce zone of British Columbia. For Ecol manag 130:17–26
  Article Google Scholar
• Wipfler P, Seifert T, Heerdt C, Werner H, Pretzsch H (2005) Growth of adult Norway spruce (Picea abies [L.] Karst.) and European beech (Fagus sylvatica L.) Under free ozone fumigation. Plant Biol 7(6):611–618
  Article PubMed CAS Google Scholar

Download references