Effect of charcoal production and woodland type on soil organic carbon and total nitrogen in drylands of southern Mozambique

Lisboa, Sá Nogueira; Woollen, Emily; Grundy, Isla; Ryan, Casey M.; Smith, Harriet Elizabeth; Zorrilla-Miras, Pedro; Baumert, Sophia; Ribeiro, Natasha; Vollmer, Frank; Holland, Margaret B.; Sitoe, Almeida

doi:10.1016/j.foreco.2019.117692

Cited by 9 publications

(5 citation statements)

References 62 publications

(67 reference statements)

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“…Finally, for savannas, we find a similar pattern as for historical charcoal regimes, and we interpret these results with the ability of savanna biomes to be more resilient to disturbances (Osborne et al, 2018; Pelletier et al, 2018; Tredennick & Hanan, 2015). For all biomes, we find little change in soil carbon, with a small increase in soil carbon stocks right after charcoal production, and this agrees with results from field studies in the savanna of Mozambique (Lisboa et al, 2020). The small increase in soil carbon is due to biomass residues during charcoal production, which later enter soil carbon stocks due to increased decomposition (Miao et al, 2019).…”

Section: Discussionsupporting

confidence: 90%

The effect of charcoal production on carbon cycling in African biomes

2023

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Using biomass for charcoal production in sub‐Saharan Africa (SSA) may change carbon stock dynamics and lead to irreversible changes in the carbon balance, yet we have little understanding of whether these dynamics vary by biome in this region. Currently, charcoal production contributes up to 7% of yearly deforestation in tropical regions, with carbon emissions corresponding to 71.2 million tonnes of CO2 and 1.3 million tonnes of CH4. With a projected increased demand for charcoal in the coming decades, even low harvest rates may throw the carbon budget off‐balance due to legacy effects. Here, we parameterized the dynamic global vegetation model LPJ‐GUESS for six SSA biomes and examined the effect of charcoal production on net ecosystem exchange (NEE), carbon stock sizes and recovery time for tropical rain forest, montane forest, moist savanna, dry savanna, temperate grassland and semi‐desert. Under historical charcoal regimes, tropical rain forests and montane forests transitioned from net carbon sinks to net sources, that is, mean cumulative NEE from −3.56 ± 2.59 kg C/m2 to 2.46 ± 3.43 kg C/m2 and −2.73 ± 2.80 kg C/m2 to 1.87 ± 4.94 kg C/m2 respectively. Varying charcoal production intensities resulted in tropical rain forests showing at least two times higher carbon losses than the other biomes. Biome recovery time varied by carbon stock, with tropical and montane forests taking about 10 times longer than the fast recovery observed for semi‐desert and temperate grasslands. Our findings show that high biomass biomes are disproportionately affected by biomass harvesting for charcoal, and even low harvesting rates strongly affect vegetation and litter carbon and their contribution to the carbon budget. Therefore, the prolonged biome recoveries imply that current charcoal production practices in SSA are not sustainable, especially in tropical rain forests and montane forests, where we observe longer recovery for vegetation and litter carbon stocks.

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Section: Discussionsupporting

confidence: 90%

The effect of charcoal production on carbon cycling in African biomes

2023

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“…The climate in this area is classified as semi-arid, with an average annual rainfall of 505 mm/year and an average annual temperature of 24 °C. The region experiences distinct dry and wet seasons, with most precipitation between October and April 32 . The vegetation in the Mabalane District primarily consists of Mopane woodlands (Colophospermum mopane (Benth.)…”

Section: Site Descriptionmentioning

confidence: 99%

“…Gilg & Gilg-Ben. 32 . The second study site is in Tambara District, situated in the central region of Mozambique in Manica province (Figure 1).…”

Section: Site Descriptionmentioning

confidence: 99%

Allometric equations and height-diameter models for estimating above-and below-ground biomass of Colophospermum mopane J.Léonard. in Mozambique

Lisboa,

Macôo,

Sitoe

2024

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This study aimed to develop species-specific biomass allometric equations (BAE) for the estimation of above-ground biomass (AGB) and below-ground biomass (BGB) of Colophospermum mopane, J.Léonard species in Mozambique and to evaluate the feasibility of including total height estimated by the height-diameter (H-D) model in the equations to improve the accuracy of biomass estimation. We applied a destructive method and felled 120 trees of C. mopane in Mabalane and Tambara districts. We measured breast height diameter, total height (H), and dry weight of each component (roots, stem, branches, and leaves). We fitted three BAE and fifteen H-D models using OLS and non-linear least squares regression. A validation procedure checked all models for applicability. We conducted a forest inventory using 78 temporary clusters, each consisting of four plots measuring 100 m x 20 m, to estimate the average AGB and BGB of C. mopane using the best-fitting BAE and H-D model. We also compared the best BAE of C. mopane with existing, locally developed species-specific BAEs. The study found that the model, including the interaction of D2 and H, performed better than the model with separate D and H variables. However, models including D and H performed similarly to models with D alone. The Power model and HossfeldIV performed best among the models with 2 and 3 parameters, respectively. Integrating the H-D model into the BAE for AGB and estimation can improve the efficiency and reliability of biomass estimation and stand volume by forest inventory data. Overall, this research is timely as there is an urgent need to improve the assessment of biomass and carbon emissions in mopane woodland (MW) in southern Africa, given their spatial extent, and to support climate goals and the sustainable management of these ecosystems.

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“…However, black carbon and charcoal can differ from biochar in production and application purposes. For instance, black carbon can be made by burning fossil fuels as well as biomass [55], while charcoal is produced mainly to provide affordable energy to rural areas and is not used solely as a soil amendment [56]. However, we do include the terms "black carbon" and "charcoal" in the intervention search terms (Table 2).…”

Section: Eligibility Criteriamentioning

confidence: 99%

Biochar’s effect on the ecosystem services provided by sandy-textured and contaminated sandy soils: a systematic review protocol

et al. 2021

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Background Biochar is a relatively new soil amendment method in agricultural practices that can improve the ecosystem services of soils. Biochar has commonly been applied to less fertile or contaminated soils, specifically sandy-textured and contaminated sandy soils, to improve their properties. However, the available literature indicates that not all sandy-textured and contaminated sandy soils show the same response to biochar applications, as the sign and size of the effect vary across studies. More specifically, primary studies show heterogeneous and potentially conflicting impacts of biochar application on a set of ecosystem services provided by these types of soils; namely, biomass production, water cycle, nutrient cycle, and climate regulation. Therefore, the objective of the present study is to systematically review the available evidence base to synthesise the impact and drivers of biochar amendments on four specific ecosystem services provided by sandy-textured and contaminated sandy soils. Methods This review follows the guideline of the Collaboration for Environmental Evidence and corresponds to the ROSES (RepOrting standards for Systematic Evidence Synthesis) reporting standard. A comprehensive search strategy will be employed to cover peer-reviewed and gray literature through bibliographic databases, organizational and institutional websites, and web searches. Search terms and strategies have been developed to identify the impact of biochar on the ecosystem services of sandy-textured soils. The search results will be screened first by their title and abstract, and then by their full text. Two literature reviewers will do this based on eligibility criteria. A validity assessment will be conducted to critically appraise and assess the validity of studies using a common validity framework for environmental studies. Data will be extracted from the studies that are found to be valid for the review. Narrative synthesis and meta-analysis will be employed to synthesise the review results.

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Effect of charcoal production and woodland type on soil organic carbon and total nitrogen in drylands of southern Mozambique

Cited by 9 publications

References 62 publications

The effect of charcoal production on carbon cycling in African biomes

The effect of charcoal production on carbon cycling in African biomes

Allometric equations and height-diameter models for estimating above-and below-ground biomass of Colophospermum mopane J.Léonard. in Mozambique

Biochar’s effect on the ecosystem services provided by sandy-textured and contaminated sandy soils: a systematic review protocol

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