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Climate warming vs ecological competition for marine tropical biodiversity and fisheries

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  • Helene Gomes
  • Coralie Kersulec
  • Luc Doyen
  • Fabian Blanchard
  • Abdoul Cisse
  • Nicolas Sanz

Abstract

Marine ecosystems, biodiversity and fisheries are under pressure worldwide because of global changes including climate warming and demographic pressure. In that regard, many scientists and stakeholders advocate the use of an ecosystem approach for fisheries integrating the numerous ecological and economic complexities at play, instead of focusing on the management of isolated target species. However, the way to operationalize such an ecosystem approach remains challenging, especially from the bioeconomic viewpoint. To achieve this, here we propose a model of intermediate complexity (MICE) relying on multi-species and multi-fleets dynamics. The model also takes into account climate change through a model of envelope for the biological growth of the fish species depending on the sea surface temperature. The model is calibrated for the small-scale fishery in French Guiana using time series of fishing landings and efforts from 2006 to 2018. From the calibrated model, we consider the business as usual (BAU) fishing intensity projection along with RCP climate scenarios derived from IPCC at the horizon 2100 in order to explore the impact of climate change on the ecosystem dynamics and on the fishery production. The results point out the detrimental impact in the long run of both climate change and ecological competition on fish biodiversity. The situation is particularly catastrophic in the pessimistic climate scenario as the results suggest the collapse of both biodiversity and fishing activities by 2100.

Suggested Citation

  • Helene Gomes & Coralie Kersulec & Luc Doyen & Fabian Blanchard & Abdoul Cisse & Nicolas Sanz, 2020. "Climate warming vs ecological competition for marine tropical biodiversity and fisheries," Bordeaux Economics Working Papers 2020-13, Bordeaux School of Economics (BSE).
    • Handle: RePEc:grt:bdxewp:2020-13
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    File URL: http://bordeauxeconomicswp.u-bordeaux.fr/2020/2020-13.pdf
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    References listed on IDEAS

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    1. John Harte & Annette Ostling & Jessica L. Green & Ann Kinzig, 2004. "Climate change and extinction risk," Nature, Nature, vol. 430(6995), pages 34-34, July.
    2. Diop, Bassirou & Sanz, Nicolas & Duplan, Yves Jamont Junior & Guene, El Hadji Mama & Blanchard, Fabian & Pereau, Jean-Christophe & Doyen, Luc, 2018. "Maximum Economic Yield Fishery Management in the Face of Global Warming," Ecological Economics, Elsevier, vol. 154(C), pages 52-61.
    3. Cissé, A.A. & Gourguet, S. & Doyen, L. & Blanchard, F. & Péreau, J.-C., 2013. "A bio-economic model for the ecosystem-based management of the coastal fishery in French Guiana," Environment and Development Economics, Cambridge University Press, vol. 18(3), pages 245-269, June.
    4. Lagarde, A. & Doyen, L. & Ahad-Cissé, A. & Caill-Milly, N. & Gourguet, S. & Pape, O. Le & Macher, C. & Morandeau, G. & Thébaud, O., 2018. "How Does MMEY Mitigate the Bioeconomic Effects of Climate Change for Mixed Fisheries," Ecological Economics, Elsevier, vol. 154(C), pages 317-332.
    5. Chris D. Thomas & Alison Cameron & Rhys E. Green & Michel Bakkenes & Linda J. Beaumont & Yvonne C. Collingham & Barend F. N. Erasmus & Marinez Ferreira de Siqueira & Alan Grainger & Lee Hannah & Lesle, 2004. "Extinction risk from climate change," Nature, Nature, vol. 427(6970), pages 145-148, January.
    6. Fabien Steinmetz & Olivier Thébaud & Fabian Blanchard & Pascal Le Floc'H & Julien Bihel, 2008. "A bio-economic analysis of long term changes in the production of French fishing fleets operating in the Bay of Biscay," Post-Print hal-00366687, HAL.
    7. Luc Doyen, 2014. "EcoViability for ecosystem based fisheries management," Post-Print hal-02274521, HAL.
    8. Paul M. Thompson & Janet C. Ollason, 2001. "Lagged effects of ocean climate change on fulmar population dynamics," Nature, Nature, vol. 413(6854), pages 417-420, September.
    9. Sanchirico, James N. & Smith, Martin D. & Lipton, Douglas W., 2008. "An empirical approach to ecosystem-based fishery management," Ecological Economics, Elsevier, vol. 64(3), pages 586-596, January.
    10. Pitcher, Tony J. & Kalikoski, Daniela & Short, Katherine & Varkey, Divya & Pramod, Ganapathiraju, 2009. "An evaluation of progress in implementing ecosystem-based management of fisheries in 33 countries," Marine Policy, Elsevier, vol. 33(2), pages 223-232, March.
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    More about this item

    Keywords

    Marine biodiversity; Multi-species; Multi-fleet fishery; Models of Intermediate Complexity (MICE); Climate change; Exclusion principle;
    All these keywords.

    JEL classification:

    • Q22 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Renewable Resources and Conservation - - - Fishery

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