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More asymmetric tree competition brings about more evapotranspiration and less runoff from the forest ecosystems: A simulation study

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  • Toda, Motomu
  • Yokozawa, Masayuki
  • Emori, Seita
  • Hara, Toshihiko

Abstract

The present paper reports how stand size–structure dynamics due to competition between different-sized trees affect long-term forested water balance in Japanese cool-temperate planted stands (evergreen coniferous Cryptomeria japonica and deciduous coniferous Larix kaempferi stands) using a fully coupled multi-layered meteorological surface physics—terrestrial ecosystems model. The simulation captured the well-known annual variation in leaf area index (LAI) accurately with stand age in monocultured and even-aged stands; the occurrence of maximum LAI during the early growth stage and then a gradual decline followed by a steady state after the maximum LAI. The simulations also detected a high dependency of annual evapotranspiration (AETr) on LAI with stand age that is well known by prior observational researches. In the C. japonica (shade-tolerant late-successional species) stand, the relationship between annual net primary productivity of an individual tree (NPPind) and individual tree mass (w) changed from linear to a convex curve during self-thinning, indicating that the degree of asymmetric tree competition intensified with forest stand development. The higher degree of competitive asymmetry characterized by the convex-shaped NPPind–w relationship produced greater size inequality, i.e., the formation of trees stratified by height. Under such conditions, AETr and annual transpiration (ATr) were mainly regulated by larger trees. On the other hand, the NPPind–w relationships in the L. kaempferi (shade-intolerant early-successional species) stand were linear throughout the simulated period, indicating the lower degree of competitive asymmetry. Under such conditions, the growth of intermediate-sized trees was enhanced and these trees became a dominant source of AETr (and also ATr) during self-thinning. Furthermore, the sensitivity analysis of the effects of ecophysiological parameters such as foliage profile (i.e., vertical distribution of leaf area density) of an individual tree (distribution pattern is described by the parameter η), the maximum carboxylation velocity (Vcmax0) and biomass allocation pattern of individual plant growth (μ1) on AETr, ATr and annual runoff (ARoff) showed that the temporal trends of AETr, ATr, ARoff and NPPind–w relationships were completely the same as those in the control simulations. However, the NPPind–w relationship during self-thinning indicated higher degrees of competitive asymmetry when η or Vcmax0 were greater than those in the control simulation and generated greater AETr and ATr and thus smaller ARoff. We found that more asymmetric tree competition brings about greater size inequality between different-sized trees and thus more evapotranspiration and less runoff in a forest stand. Overall, our simulation approach revealed that not only LAI dynamics but also plant competition, and thus size–structure dynamics, in a forest ecosystem are essential to long-term future projections of forested water balance.

Suggested Citation

  • Toda, Motomu & Yokozawa, Masayuki & Emori, Seita & Hara, Toshihiko, 2010. "More asymmetric tree competition brings about more evapotranspiration and less runoff from the forest ecosystems: A simulation study," Ecological Modelling, Elsevier, vol. 221(24), pages 2887-2898.
    • Handle: RePEc:eee:ecomod:v:221:y:2010:i:24:p:2887-2898
    DOI: 10.1016/j.ecolmodel.2010.08.025
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    References listed on IDEAS

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    1. Toda, Motomu & Yokozawa, Masayuki & Sumida, Akihiro & Watanabe, Tsutomu & Hara, Toshihiko, 2009. "Foliage profiles of individual trees determine competition, self-thinning, biomass and NPP of a Cryptomeria japonica forest stand: A simulation study based on a stand-scale process-based forest model," Ecological Modelling, Elsevier, vol. 220(18), pages 2272-2280.
    2. N. Gedney & P. M. Cox & R. A. Betts & O. Boucher & C. Huntingford & P. A. Stott, 2006. "Detection of a direct carbon dioxide effect in continental river runoff records," Nature, Nature, vol. 439(7078), pages 835-838, February.
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    1. Yan, Yan & Yang, Zhifeng & Liu, Qiang, 2013. "Nonlinear trend in streamflow and its response to climate change under complex ecohydrological patterns in the Yellow River Basin, China," Ecological Modelling, Elsevier, vol. 252(C), pages 220-227.
    2. Sawano, Shinji & Hotta, Norifumi & Tanaka, Nobuaki & Tsuboyama, Yoshio & Suzuki, Masakazu, 2015. "Development of a simple forest evapotranspiration model using a process-oriented model as a reference to parameterize data from a wide range of environmental conditions," Ecological Modelling, Elsevier, vol. 309, pages 93-109.

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