MansuyBarretteLaganiereEtAl2018

Référence

Mansuy, N., Barrette, J., Laganière, J., Mabee, W., Pare, D., Gautam, S., Thiffault, E. and Ghafghazi, S. (2018) Salvage harvesting for bioenergy in Canada: From sustainable and integrated supply chain to climate change mitigation. Wiley Interdisciplinary Reviews: Energy and Environment, 7(5). (Scopus )

Résumé

Driven by the policy imperatives of mitigating greenhouse gas (GHG) emissions and improving energy security, an increasing proportion of global energy demand is being met by nonfossil energy sources. The socioeconomic and environmental benefits of replacing fossil fuels with bioenergy are complex; however, debate continues about issues such as best practices for biomass removal, stable supply chains, and GHG mitigation. With the greatest biomass per capita in the world, Canada could play an increasing role in the future of global bioenergy and the emerging bioeconomy. This paper reviews the utilization of feedstock salvaged after natural disturbances (fire and insect outbreaks) to supply wood-based bioenergy, by addressing the following multidisciplinary questions: (1) How much salvaged feedstock is available, and what are the uncertainties around these estimates? (2) How can sustainable practices to support increased removal of biomass be implemented? (3) What are the constraints on development of an integrated supply chain and cost-effective mobilization of the biomass? (4) Is the quality of biomass from salvaged trees suitable for conversion to bioenergy? (5) What is the potential for climate change mitigation? In average, salvaged feedstock from fire and insects could theoretically provide about 100 × 106 oven Dry ton (ODT) biomass per year, with high variability over time and space. Existing policies and guidelines for harvesting of woody biomass in Canadian jurisdictions could support sustainable biomass removal. However, uncertainties remain as to the development of competitive and profitable supply chains, because of the large distances between the locations of this feedstock and available processing sites. Another uncertainty lies in the time needed for a benefit in climate change mitigation to occur. A flexible supply chain, integrated with other sources of biomass residues, is needed to develop a cost-efficient bioenergy sector. This article is categorized under: Bioenergy > Climate and Environment. © 2018 Her Majesty the Queen in Right of Canada WIREs Energy and Environment © 2018 Wiley Periodicals, Inc. Reproduced with the permission of the Minister of Natural Resources Canada.

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@ARTICLE { MansuyBarretteLaganiereEtAl2018,
    AUTHOR = { Mansuy, N. and Barrette, J. and Laganière, J. and Mabee, W. and Pare, D. and Gautam, S. and Thiffault, E. and Ghafghazi, S. },
    TITLE = { Salvage harvesting for bioenergy in Canada: From sustainable and integrated supply chain to climate change mitigation },
    JOURNAL = { Wiley Interdisciplinary Reviews: Energy and Environment },
    YEAR = { 2018 },
    VOLUME = { 7 },
    NUMBER = { 5 },
    NOTE = { cited By 1 },
    ABSTRACT = { Driven by the policy imperatives of mitigating greenhouse gas (GHG) emissions and improving energy security, an increasing proportion of global energy demand is being met by nonfossil energy sources. The socioeconomic and environmental benefits of replacing fossil fuels with bioenergy are complex; however, debate continues about issues such as best practices for biomass removal, stable supply chains, and GHG mitigation. With the greatest biomass per capita in the world, Canada could play an increasing role in the future of global bioenergy and the emerging bioeconomy. This paper reviews the utilization of feedstock salvaged after natural disturbances (fire and insect outbreaks) to supply wood-based bioenergy, by addressing the following multidisciplinary questions: (1) How much salvaged feedstock is available, and what are the uncertainties around these estimates? (2) How can sustainable practices to support increased removal of biomass be implemented? (3) What are the constraints on development of an integrated supply chain and cost-effective mobilization of the biomass? (4) Is the quality of biomass from salvaged trees suitable for conversion to bioenergy? (5) What is the potential for climate change mitigation? In average, salvaged feedstock from fire and insects could theoretically provide about 100 × 106 oven Dry ton (ODT) biomass per year, with high variability over time and space. Existing policies and guidelines for harvesting of woody biomass in Canadian jurisdictions could support sustainable biomass removal. However, uncertainties remain as to the development of competitive and profitable supply chains, because of the large distances between the locations of this feedstock and available processing sites. Another uncertainty lies in the time needed for a benefit in climate change mitigation to occur. A flexible supply chain, integrated with other sources of biomass residues, is needed to develop a cost-efficient bioenergy sector. This article is categorized under: Bioenergy > Climate and Environment. © 2018 Her Majesty the Queen in Right of Canada WIREs Energy and Environment © 2018 Wiley Periodicals, Inc. Reproduced with the permission of the Minister of Natural Resources Canada. },
    AFFILIATION = { Natural Resources Canada, Canadian Forest Service, Northern Forestry Centre, Edmonton, AB, Canada; Natural Resources Canada, Laurentian Forestry Centre, Canadian Forest ServiceQC, Canada; Department of Geography and Planning, Queen's University, Kingston, ON, Canada; College of Natural Resources, University of Wisconsin - Stevens Point, Stevens Point, WI, United States; Research Centre on Renewable Materials, Department of wood and forest sciences, Université LavalQC, Canada; Faculty of Forestry, University of British Columbia, Vancouver, BC, Canada },
    ART_NUMBER = { e298 },
    AUTHOR_KEYWORDS = { biofuel; biomass; boreal forest; fire; insect, integrated supply chain; low-carbon economy; natural disturbance; pellet },
    DOCUMENT_TYPE = { Review },
    DOI = { 10.1002/wene.298 },
    SOURCE = { Scopus },
    URL = { https://www.scopus.com/inward/record.uri?eid=2-s2.0-85051863010&doi=10.1002%2fwene.298&partnerID=40&md5=a9ef9ee08096c3f67b403294783a338b },
}

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