Periodic Reporting for period 4 - HEFT (Hidden Emissions of Forest Transitions: GHG effects of socio-metabolic processes reducingpressures on forests)
Okres sprawozdawczy: 2022-10-01 do 2024-03-31
In case studies in Europe since c. 1850, North America since c.1880 and Southeast Asia since 1980, as well as globally, the project investigated processes such as substitution of fuelwood by modern energy sources, intensification of agriculture, and land displacement, in terms of their climate impacts. We integrated sources and analytical methods from environmental and social sciences as well as the humanities to analyze context-specific trajectories and general interlinkages of forest transitions and resource use in various socio-political contexts. The sound understanding of the links between forest change and resource use was used to identify options for sustainable forest recovery, and to draw lessons for land-based climate-change mitigation policies that are both ecologically and socially sustainable.
Major quantitative and qualitative efforts were conducted to analyze trajectories of forest transitions and their connections to resource use and socio-political dynamics in diverse geographical and historical contexts. Counterfactual scenario approaches, decomposition analyses, and regression analyses were applied to quantitatively assess and compare the relative contributions of changes in specific trends of resource use to forest change, as well as their emissions impacts. Combining quantitative methods of environmental accounting with qualitative methods from political ecology and environmental history, we investigated similarities and differences of these processes across case studies in terms of both their biophysical and socio-political dimensions.
We also explored options for sustainable forest conservation, investigating how the use of wood products and biomass more generally could reconcile meeting societal needs while respecting ecological boundaries including, but not limited to, carbon sequestration.
The project developed accounting methods and models to reconstruct regional, national and global-level forest and ecosystem carbon dynamics and greenhouse gas emissions from agriculture in time periods of 100 to 200 years. This allowed to quantify the climate impact of long-term forest recovery, and to assess major factors that drove these changes. A particularly innovative approach developed in the project was the historical counterfactual analysis. This way, we were able to show, for example, that globally since 1990, gross forest recovery resulted from increased average tree growth rates, rather than from forest area expansion.
The project also made major methodological contributions in conntecting biophysical reconstructions of forest and land-use change with assessments of social and political dynamics that shaped them. We found that the reduction of agricultural practices in forests (e.g. forest grazing in temperate regions and shifting cultivation in the tropics) was an important factor accompanying forest transitions across case studies, coinciding with ecological (i.e. enhanced tree growth) and social dynamics (i.e. reduced access to forests). In addition, we found that efficiency gains in land and resource use were important, but overcompensated by increases in consumption (e.g. more energy use, more livestock product consumption), resulting in growing emissions in the long run.
We identified land sharing strategies, e.g. through agroforestry, as potentially viable land-use options that integrate socially just forest use with reduced climate impacts. Furthermore, we found that changes in the entire supply chain, from production to consumption, are required to allow for ecologically sustainable biomass production to meet human needs. Important levers include reductions in livestock production and consumption and a shift in wood use from bioenergy towards long-lived products.