Managing temperate forests for carbon storage: impacts of logging versus forest protection on carbon stocks

Management of native forests offers opportunities to store more carbon in the land sector through two main activities. Emissions to the atmosphere can be avoided by ceasing logging. Removals of carbon dioxide from the atmosphere can be increased by allowing forests to continue growing. However, the...

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Published inEcosphere (Washington, D.C) Vol. 5; no. 6; pp. art75 - 34
Main Authors Keith, Heather, Lindenmayer, David, Mackey, Brendan, Blair, David, Carter, Lauren, McBurney, Lachlan, Okada, Sachiko, Konishi-Nagano, Tomoko
Format Journal Article
LanguageEnglish
Published Washington Ecological Society of America 01.06.2014
John Wiley & Sons, Inc
Subjects
Atmosphere
Biodiversity
Biomass
carbon accounting
Carbon dioxide
carbon emissions
Carbon sequestration
carbon storage
Climate change
disturbances
Ecosystems
Emissions
Environmental conditions
Eucalyptus regnans
Forest management
forest management logging
Forest protection
Landfills
Logging
Longevity
montane ash forest
native forest
Old growth
old growth forest
Temperate forests
Vegetation
Waste disposal sites
Wildfires
Wood
Australia
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Summary:Management of native forests offers opportunities to store more carbon in the land sector through two main activities. Emissions to the atmosphere can be avoided by ceasing logging. Removals of carbon dioxide from the atmosphere can be increased by allowing forests to continue growing. However, the relative benefits for carbon storage of managing native forests for wood production versus protection are contested. Additionally, the potential for carbon storage is impacted upon by disturbance events, such as wildfire, that alter the amount and longevity of carbon stocks. Using a case study of montane ash forests in southeastern Australia, we demonstrated that the total biomass carbon stock in logged forest was 55% of the stock in old growth forest. Total biomass included above- and belowground, living and dead. Biomass carbon stock was calculated spatially as an average across the landscape, accounting for variation in environmental conditions and forest age distribution. Reduction in carbon stock in logged forest was due to 66% of the initial biomass being made into products with short lifetimes (<3 years), and to the lower average age of logged forest (<50 years compared with >100 years in old growth forest). Only 4% of the initial carbon stock in the native forest was converted to sawn timber products with lifetimes of 30-90 years. Carbon stocks are depleted in a harvested forest system compared with an old growth forest, even when storage in wood products and landfill are included. We estimated that continued logging under current plans represented a loss of 5.56 Tg C over 5 years in the area logged (824 km 2 ), compared with a potential gain of 5.18-6.05 TgC over 5 years by allowing continued growth across the montane ash forest region (2326 km 2 ). Avoiding emissions by not logging native forests and allowing them to continue growing is therefore an important form of carbon sequestration. The mitigation value of forest management options of protection versus logging should be assessed in terms of the amount, longevity and resilience of the carbon stored in the forest, rather than the annual rate of carbon uptake.
Bibliography:Corresponding Editor: Y. Pan.
ISSN:2150-8925
2150-8925
DOI:10.1890/ES14-00051.1