Ontario’s managed forests and harvested wood products contribute to greenhouse gas mitigation from 2020 to 2100
We used an integrated approach to estimate the greenhouse gas (GHG) mitigation potential of Ontario’s forestry sector, defined as the managed forests and the harvested wood products (HWP) originating from these forests. The 44.7 million ha of managed forests in this study included Crown forests desi...
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| Main Authors: | , , , |
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| Format: | Article |
| Language: | English |
| Published: |
Canadian Institute of Forestry
2018-10-01
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| Series: | The Forestry Chronicle |
| Subjects: | |
| Online Access: | https://pubs.cif-ifc.org/doi/10.5558/tfc2018-040 |
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| Summary: | We used an integrated approach to estimate the greenhouse gas (GHG) mitigation potential of Ontario’s forestry sector, defined as the managed forests and the harvested wood products (HWP) originating from these forests. The 44.7 million ha of managed forests in this study included Crown forests designated as 41 forest management units (FMUs) for timber harvesting, productive forests north of the area of undertaking, large parks, and private forest land. Forests and HWP were simulated from approximately 2010 to 2100, with carbon (C) stocks and emissions reported for the period 2020 to 2100. A baseline scenario was defined to represent business as usual forestry operations in Ontario, in which the 41 FMUs and the private forests were harvested at historical (1990–2009) rates, and HWP production and end uses were assumed to follow Ontario’s historical values (1991–2010). In the baseline scenario, the forest C stocks were projected to increase from 7229.7 million tonnes (Mt C) in 2020 to 7424 Mt C in 2100. The C stocks of HWP originating from the 41 FMUs and the private forests were estimated to increase from 171.0 Mt C, the initial HWP C stocks in 2020 from previous harvesting, to 334.7 Mt C in 2100, in which the C stocks of HWP in use and in landfills, HWP production emissions, landfill methane emissions from decomposing mill residue and waste HWP discarded, and the reduced emissions from substituting HWP for non-wood materials in construction were all considered. On average, Ontario’s forestry sector was estimated to increase C stocks by 44.8 Mt per decade over the 80-year period. Six alternative scenarios were defined based on increased harvesting in the 41 FMUs and varied use of the increased harvested wood in HWP production and differing HWP end uses. Depending on how the increased harvested wood is used, increased forest harvesting (relative to historical rates) may increase or reduce the mitigation potential of Ontario’s forestry sector. Based on historical use statistics, the life-cycle analysis HWP C stocks/emissions plus HWP substitution benefits were insufficient to compensate for forest C decreases from increased harvesting. However, if the increased harvested wood was used to produce solid HWP and these products were used in construction, increasing forest harvesting to 95% of the maximum allowable harvest level would require 20.0 years to achieve a positive net mitigation contribution. Factoring out the decrease in forest C due to increased harvesting, this amounts to 187.9 Mt C of additional mitigation contribution by 2100. We conclude that Ontario’s forestry sector has the potential to contribute significantly to medium- and long-term GHG mitigation. Our results indicate that harvesting sustainably managed forests to produce solid HWP and using these HWP in long-lived end uses such as construction is a better mitigation option than protecting forest from harvesting. |
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| ISSN: | 0015-7546 1499-9315 |