Litcius/Paper detail

Climate change substitution factors for Canadian forest-based products and bioenergy

Thomas Cardinal, Charles Alexandre, Thomas Elliot, Hamed Kouchaki‐Penchah, Annie Levasseur

2024Ecological Indicators13 citationsDOIOpen Access PDF

Abstract

Evaluating the climate change mitigation potential of the forest sector requires a holistic approach based on forest carbon (C) sequestration, C storage in harvested wood products (HWP) and substitution on markets. High uncertainty is associated with substitution factors, that express avoided fossil greenhouse gas (GHG) emissions from the use of forest-based products in replacement of GHG-intensive materials and fossil fuels. Few studies have focused on the development of substitution factors in Canada, resulting in the use of unrepresentative generic data. Here, we provide a framework to reduce uncertainties related to substitution factors for primary wood products in a Canadian context. A life cycle assessment framework is used to quantify fossil GHG emissions for a baseline and a wood-intensive scenario. For solid product substitution, we focused on the construction sector and analyzed a range of innovative wood buildings with steel and reinforced concrete as alternative materials. We found non-weighted averages of 0.80 tC/tC for sawnwood and 0.81 tC/tC for panels. For energy substitution, we analyzed cases with different specifications on biomass product, facility type and alternative fossil fuel source in non-residential heat production and biofuel transportation sectors. We found a non-weighted average of 0.80 tC/tC for non-residential heat production and 0.51 tC/tC for biofuel transportation, that can be interpreted as 0.91 tC/tC for heavy fuel oil, 0.69 tC/tC for light fuel oil and 0.68 tC/tC for natural gas substitution. These results provide a benchmark for substitution factors in Canada, to help guide forest management strategies for climate change mitigation.

Topics & Concepts

Greenhouse gasFossil fuelEnvironmental scienceBiofuelBiomass (ecology)BioenergyCarbon sequestrationLife-cycle assessmentClimate change mitigationContext (archaeology)Renewable energyWaste managementProduction (economics)EngineeringEcologyCarbon dioxideGeographyEconomicsElectrical engineeringBiologyArchaeologyMacroeconomicsEnvironmental Impact and SustainabilityForest Biomass Utilization and ManagementThermochemical Biomass Conversion Processes