Organic carbon stocks in all pools following land cover change in the rainforest of Madagascar

Deforestation is mainly due to slash-and-burn agriculture which results in a mosaic of land use types where fallows are prevalent

Abstract

Terrestrial ecosystems represent the most imprtant carbon (c) sink with their capacity to store almost three times that of the atmosphere. Further, approximately 40% of terrestrial C is stored in tropical forests, sequestering large amounts of carbon dioxide from the atmosphere. However, these forests are threatened by high rates of conversion to other land uses, constituting a major source of greenhouse gas (GHG) emissions and contributin to climate change . The UN initiative, Reducing Emissions from Deforestation and Forest Degradation (REDD+), represents one path aimed at mitigating the impacts of climate change by conserving tropical forests threatened by deforestation or degradation. It aims to reduce carbon dioxide emissions from developing countries through the sustainable managment of forests, while providing co-benefits of biodiversity conservation and livelihood support. Accurate carbon stock quantification represents one important step in ensuring the successful implementation of REDD+, as such information is needed for validation and verification of emissions reductions.

In eastern Madagascar, deforestation is mainly due to slash-and-burn agriculture , which results in a mosaic of land use types where fallows are prevalent. To address deforestation in one area of this region, many activities have been implemented, including the development of a REDD+ project initiated by the Government of Madagascar in 2008 (Conservation International, 2013). REDD+ demands a precise estimation of the amount of C stored in forest and other land use types in order to accurately calculate, for example, the emissions avoided due to the presence of a REDD+ project (Andriamananjara et al., 2016). This is needed because the contribution of the C pools may vary across the landscape. The majority of studies to date on C accounting in different forest ecosystems in Madagascar considered separately the C pools, while studies of the estimation of C stock that consider all five C pools are scarce,

In this chapter, we firstly review a recent study that accounted C stocks in all five pools recognized by the IPCC (2003), including AGB, BGB, litter, deadwood (DW), and SOC. Afterwards, we identify their dynamics across land uses following deforestation

Citation

Razafindrakoto, M.; Andriamananjara, A.; Razafimbelo, T.; Hewson, J.; Andrisoa, R.H.; Jones, J.P.G.; van Meerveld, I.; Cameron, A.; Ranaivoson, N.; Ramifehiarivo, N.; Ramboatiana, N.; Razafinarivo, R.N.G.; Ramananantoandro, T.; Rasolohery, A.; Razafimanantsoa, M.P.; Jourdan, C.; Saint-Andre, L.; Rajoelison, G.; Razakamanarivo, H. (2017) Organic carbon stocks in all pools following land cover change in the rainforest of Madagascar. Soil management and climate change: effects on organic carbon, nitrogen dynamics and greenhouse gas emissions, pp.396, Academic Press, 2017

Organic carbon stocks in all pools following land cover change in the rainforest of Madagascar

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Published 31 January 2017