Limited role of shifting cultivation in soil carbon and nutrients recovery in regenerating tropical secondary forests

Mukul, Sharif A.; Herbohn, John; Ferraren, Angela; Congdon, Robert A.

doi:10.3389/fenvs.2022.1076506

Cited by 5 publications

(3 citation statements)

References 97 publications

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“…The initial differences of soil quality may influence farmers' land use decision and leads to a bias of the space-for-time approach used in our study (a negative trend of SOC stock across forest successional gradients). However, recent studies have suggested that soil fertility recovers to 90% of oldgrowth forest values within 10 years of land abandonment from agriculture activities (Poorter et al, 2021), and the highest rate of soil no-change (Bruun et al, 2021), gain (Gogoi et al, 2020) and loss (Sugihara et al, 2019) or fluctuation with fallow age (Chan et al, 2016;Mukul et al, 2022), but SOC tends to recover rapidly during the first 2 years of a fallow period (Lungmuana et al, 2017). Our models did not detect significant direct effects of forest succession on SOC stock (Figure 4).…”

Section: Soil Organic Carbon Stock and Forest Successioncontrasting

confidence: 69%

“…However, recent studies have suggested that soil fertility recovers to 90% of old‐growth forest values within 10 years of land abandonment from agriculture activities (Poorter et al, 2021), and the highest rate of soil carbon sequestration occurs during the first 15 years (Bautista‐Cruz & del Castillo, 2005). Scientists hypothesized that SOC stock increases with forest age (Powers & Marín‐Spiotta, 2017), but evidence from field studies on shifting cultivation systems varies and includes no‐change (Bruun et al, 2021), gain (Gogoi et al, 2020) and loss (Sugihara et al, 2019) or fluctuation with fallow age (Chan et al, 2016; Mukul et al, 2022), but SOC tends to recover rapidly during the first 2 years of a fallow period (Lungmuana et al, 2017). Our models did not detect significant direct effects of forest succession on SOC stock (Figure 4).…”

Section: Discussionmentioning

confidence: 99%

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Drivers of soil organic carbon stock during tropical forest succession

et al. 2023

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1. Soil organic matter contributes to productivity in terrestrial ecosystems and contains more carbon than is found in the atmosphere. Yet, there is little understanding of soil organic carbon (SOC) sequestration processes during tropical forest succession, particularly after land abandonment from agriculture practices.2. Here, we used vegetation and environmental data from two large-scale surveys covering a total landscape area of 20,000 ha in Southeast Asia to investigate the effects of plant species diversity, functional trait diversity, phylogenetic diversity, above-ground biomass and environmental factors on SOC sequestration during forest succession.3. We found that functional trait diversity plays an important role in determining SOC sequestration across successional trajectories. Increases in SOC carbon storage were associated with indirect positive effects of species diversity and succession age via functional trait diversity, but phylogenetic diversity and aboveground biomass showed no significant relationship with SOC stock. Furthermore, the effects of soil properties and functional trait diversity on SOC carbon storage shift across elevation. 4. Synthesis. Our results suggest that reforestation and restoration management practices that implement a trait-based approach by combining long-lived and short-lived species (conservative and acquisitive traits) to increase plant functional diversity could enhance SOC sequestration for climate change mitigation and adaptation efforts, as well as accelerate recovery of healthy soils.

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Section: Soil Organic Carbon Stock and Forest Successioncontrasting

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Drivers of soil organic carbon stock during tropical forest succession

et al. 2023

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“…Cecilio Rebola et al 2021;Mukul et al 2022;Primo et al 2023), highlighting the potential of AFSs to restore functional aspects in the Amazon. The practice of burning plant residues and the use of mineral fertilizers may have contributed to the increase in soil acidity over time, as these practices reduce soil pH and favor the release of hydrogen ions (H+) and aluminum (Al + 3) (Chaves et al 2020).…”

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confidence: 99%

Physical and chemical soil quality and litter stock in agroforestry systems in the Eastern Amazon

de Souza,

Santos,

Martins

et al. 2024

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The influence of biodiversity and age of agroforestry systems (AFS) on the provision of ecosystem services, such as nutrient cycling, needs to be better understood to support management practices that promote such services. This study aimed to quantify and compare litter stock and the physical and chemical attributes of soil in four AFSs with different ages and arrangements to a secondary forest (FLO) in the Eastern Amazon. Litter stock did not differ among the AFSs, but the youngest AFS was lower (5.73 ± 1.04 Mg ha− 1) than in FLO (11.42 ± 2.44 Mg ha− 1). Similarities were found between FLO and the oldest AFS for most of the soil chemical attributes. The soil pH in AFSs was higher than in FLO in the surface layer, and the organic matter content of FLO did not differ from 2 and 51-year-old AFSs. The Al content and aluminum saturation of younger and 26 years-old AFSs were lower than in FLO. Particle density and total porosity did not differ among ecosystems, while soil density in the two younger AFSs was higher than in FLO. According to PCA results, variables such as organic matter, CECpH7, H + Al, Al content, and m % tended to be higher in FLO and oldest AFS. It was evident that the maturity and diversity of AFSs are relevant factors for Amazonian agroforests, as they offer positive impacts on ecosystem functionality, such as nutrient cycling and water retention.

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