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Carbon turnover in mixed stands: Modelling possible shifts under climate change

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  • Shanin, Vladimir
  • Komarov, Alexander
  • Khoraskina, Yulia
  • Bykhovets, Sergey
  • Linkosalo, Tapio
  • Mäkipää, Raisa

Abstract

Adaptation of forest management to changing climate may lead to remarkable changes in tree species composition. Deciduous species are predicted to be favoured in a warmer climate, but the competitive capacity of different tree species requires detailed analysis. The main objectives of this study were to assess how varied initial proportions of tree species affected productivity in mixed stands, and to evaluate the biomass production and carbon sequestration potential of trees and soil in mixed stands in a changing climate. We used the individual-based simulation model EFIMOD combined with the model of soil organic matter dynamics ROMUL to simulate spatially explicit competition between trees for light and nutrients. We focused our simulations on the most common type of site (mesic site, Myrtillus type) in southern Finland. The average carbon and nitrogen pools in the forest floor and mineral soil were used as initial soil data. The ambient climate scenario was based on measured data (1961–2007) from the Finnish Meteorological Institute. Climate change scenarios were based on runs of three general circulation models. We simulated the forest stand dynamics of two- and three-species mixtures (Silver birch, Scots pine and Norway spruce) with different initial proportions. In mixed spruce–birch stands, spruce replaced birch whatever the initial density, regardless of climatic scenario. In the beginning of the development of mixed spruce–pine stands, pine grew faster and increased its proportion of biomass by 10–20%. In pine–birch stands, the dominant species maintained its dominating position, but the proportion of pine generally declined by the end of simulation in birch-dominated stands. In mixed stands of three tree species, spruce tended to dominate by the end of a 100-year simulation period, independently of the initial proportions. The highest average carbon stock in standing biomass was observed in mixed stands with three species and in spruce-dominated stands. Climate change increased stand productivity and the increase in coniferous stands was more remarkable than in birch-dominated stands. In addition, soil was affected by species composition: increased proportions of pine resulted in increasing carbon stocks in the forest floor. Climate change negatively affected accumulation of organic matter in soil, especially in the spruce-dominated stands.

Suggested Citation

  • Shanin, Vladimir & Komarov, Alexander & Khoraskina, Yulia & Bykhovets, Sergey & Linkosalo, Tapio & Mäkipää, Raisa, 2013. "Carbon turnover in mixed stands: Modelling possible shifts under climate change," Ecological Modelling, Elsevier, vol. 251(C), pages 232-245.
    • Handle: RePEc:eee:ecomod:v:251:y:2013:i:c:p:232-245
    DOI: 10.1016/j.ecolmodel.2012.12.015
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    References listed on IDEAS

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    1. Shanin, Vladimir N. & Komarov, Alexander S. & Mikhailov, Alexey V. & Bykhovets, Sergei S., 2011. "Modelling carbon and nitrogen dynamics in forest ecosystems of Central Russia under different climate change scenarios and forest management regimes," Ecological Modelling, Elsevier, vol. 222(14), pages 2262-2275.
    2. Grabarnik, Pavel & Särkkä, Aila, 2009. "Modelling the spatial structure of forest stands by multivariate point processes with hierarchical interactions," Ecological Modelling, Elsevier, vol. 220(9), pages 1232-1240.
    3. Mingkui Cao & F. Ian Woodward, 1998. "Dynamic responses of terrestrial ecosystem carbon cycling to global climate change," Nature, Nature, vol. 393(6682), pages 249-252, May.
    4. R. B. Myneni & C. D. Keeling & C. J. Tucker & G. Asrar & R. R. Nemani, 1997. "Increased plant growth in the northern high latitudes from 1981 to 1991," Nature, Nature, vol. 386(6626), pages 698-702, April.
    5. Wilfried Thuiller, 2007. "Climate change and the ecologist," Nature, Nature, vol. 448(7153), pages 550-552, August.
    6. Michel Loreau & Andy Hector, 2001. "Partitioning selection and complementarity in biodiversity experiments," Nature, Nature, vol. 412(6842), pages 72-76, July.
    7. Karjalainen, Timo & Pussinen, Ari & Liski, Jari & Nabuurs, Gert-Jan & Eggers, Thies & Lapvetelainen, Tuija & Kaipainen, Terhi, 2003. "Scenario analysis of the impacts of forest management and climate change on the European forest sector carbon budget," Forest Policy and Economics, Elsevier, vol. 5(2), pages 141-155, July.
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    Cited by:

    1. Alexandrov, G.A & Golitsyn, G.S., 2015. "Biological age from the viewpoint of the thermodynamic theory of ecological systems," Ecological Modelling, Elsevier, vol. 313(C), pages 103-108.
    2. Laine-Kaulio, Hanne & Koivusalo, Harri & Komarov, Alexander S. & Lappalainen, Mari & Launiainen, Samuli & Laurén, Ari, 2014. "Extending the ROMUL model to simulate the dynamics of dissolved and sorbed C and N compounds in decomposing boreal mor," Ecological Modelling, Elsevier, vol. 272(C), pages 277-292.

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