How does management affect soil C sequestration and greenhouse gas fluxes in boreal and temperate forests? – A review
•Forest management have positive and negative effects on soil C stocks and GHG fluxes.•Intensive thinning and harvesting decrease soil C stock.•Coniferous tree species and fertilization increase soil C stock.•On drained peatlands, loss of soil C can be reduced by elevated water level.•Further unders...
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Veröffentlicht in: | Forest ecology and management 2023-02, Vol.529, p.120637, Article 120637 |
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Zusammenfassung: | •Forest management have positive and negative effects on soil C stocks and GHG fluxes.•Intensive thinning and harvesting decrease soil C stock.•Coniferous tree species and fertilization increase soil C stock.•On drained peatlands, loss of soil C can be reduced by elevated water level.•Further understanding on soil C stabilization process and microbial processes needed.
The global forest carbon (C) stock is estimated at 662 Gt of which 45% is in soil organic matter. Thus, comprehensive understanding of the effects of forest management practices on forest soil C stock and greenhouse gas (GHG) fluxes is needed for the development of effective forest-based climate change mitigation strategies. To improve this understanding, we synthesized peer-reviewed literature on forest management practices that can mitigate climate change by increasing soil C stocks and reducing GHG emissions. We further identified soil processes that affect soil GHG balance and discussed how models represent forest management effects on soil in GHG inventories and scenario analyses to address forest climate change mitigation potential.
Forest management effects depend strongly on the specific practice and land type. Intensive timber harvesting with removal of harvest residues/stumps results in a reduction in soil C stock, while high stocking density and enhanced productivity by fertilization or dominance of coniferous species increase soil C stock. Nitrogen fertilization increases the soil C stock and N2O emissions while decreasing the CH4 sink. Peatland hydrology management is a major driver of the GHG emissions of the peatland forests, with lower water level corresponding to higher CO2 emissions. Furthermore, the global warming potential of all GHG emissions (CO2, CH4 and N2O) together can be ten-fold higher after clear-cutting than in peatlands with standing trees.
The climate change mitigation potential of forest soils, as estimated by modelling approaches, accounts for stand biomass driven effects and climate factors that affect the decomposition rate. A future challenge is to account for the effects of soil preparation and other management that affects soil processes by changing soil temperature, soil moisture, soil nutrient balance, microbial community structure and processes, hydrology and soil oxygen concentration in the models. We recommend that soil monitoring and modelling focus on linking processes of soil C stabilization with the functioning of soil microbiota. |
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ISSN: | 0378-1127 1872-7042 |
DOI: | 10.1016/j.foreco.2022.120637 |