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Boreal forest management and its effect on atmospheric CO2

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  • Holtsmark, Bjart

Abstract

In a recent contribution, Cherubini et al. (2011a) analyzed numerically the effect on atmospheric carbon of a single-harvest event in a boreal forest with subsequent combustion of the extracted biomass. Those authors found that a period of increased atmospheric carbon was followed by a period of reduced atmospheric carbon, while harvest was found to be carbon neutral in the long term. First, this article shows that their results are sensitive to the choice of baseline scenario. A more realistic baseline scenario was considered here, where the stand's growth and carbon capture continue in the case of no harvest. This leads to a significantly longer period with increased atmospheric carbon than was found in Cherubini et al. (2011a). Second, the single-harvest approach is supplemented with an analysis of a series of repeated harvests to make the analysis relevant for a discussion of the consequences of the use of biomass for energy purposes, now and in the future. This changes the results fundamentally. It is found that extracting biomass from boreal forests on a permanent basis leads to permanently increased atmospheric carbon concentration when compared with the no-harvest scenario.

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  • Holtsmark, Bjart, 2013. "Boreal forest management and its effect on atmospheric CO2," Ecological Modelling, Elsevier, vol. 248(C), pages 130-134.
  • Handle: RePEc:eee:ecomod:v:248:y:2013:i:c:p:130-134
    DOI: 10.1016/j.ecolmodel.2012.10.006
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    References listed on IDEAS

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    1. Cherubini, Francesco & Strømman, Anders H. & Hertwich, Edgar, 2011. "Effects of boreal forest management practices on the climate impact of CO2 emissions from bioenergy," Ecological Modelling, Elsevier, vol. 223(1), pages 59-66.
    2. Holtsmark, Bjart & Hoel, Michael & Holtsmark, Katinka, 2013. "Optimal harvest age considering multiple carbon pools – A comment," Journal of Forest Economics, Elsevier, vol. 19(1), pages 87-95.
    3. Michael Scorgie & John Kennedy, 1996. "Who Discovered the Faustmann Condition?," History of Political Economy, Duke University Press, vol. 28(1), pages 77-80, Spring.
    4. Hoel, Michael & Holtsmark, Bjart & Holtsmark, Katinka, 2014. "Faustmann and the climate," Journal of Forest Economics, Elsevier, vol. 20(2), pages 192-210.
    5. G. Cornelis van Kooten & Clark S. Binkley & Gregg Delcourt, 1995. "Effect of Carbon Taxes and Subsidies on Optimal Forest Rotation Age and Supply of Carbon Services," American Journal of Agricultural Economics, Agricultural and Applied Economics Association, vol. 77(2), pages 365-374.
    6. Bjart Holtsmark, 2012. "Harvesting in boreal forests and the biofuel carbon debt," Climatic Change, Springer, vol. 112(2), pages 415-428, May.
    7. Haberl, Helmut & Sprinz, Detlef & Bonazountas, Marc & Cocco, Pierluigi & Desaubies, Yves & Henze, Mogens & Hertel, Ole & Johnson, Richard K. & Kastrup, Ulrike & Laconte, Pierre & Lange, Eckart & Novak, 2012. "Correcting a fundamental error in greenhouse gas accounting related to bioenergy," Energy Policy, Elsevier, vol. 45(C), pages 18-23.
    8. Samuelson, Paul A, 1976. "Economics of Forestry in an Evolving Society," Economic Inquiry, Western Economic Association International, vol. 14(4), pages 466-492, December.
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    Cited by:

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    3. Albers, Ariane & Collet, Pierre & Lorne, Daphné & Benoist, Anthony & Hélias, Arnaud, 2019. "Coupling partial-equilibrium and dynamic biogenic carbon models to assess future transport scenarios in France," Applied Energy, Elsevier, vol. 239(C), pages 316-330.

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    Keywords

    Bioenergy; Forest biomass; CO2 emissions; Global warming;
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