Fallow Reduces Soil Losses and Increases Carbon Stock in Caatinga

Almeida, Cicero Lima de; Araújo, José Carlos de; Costa, Mírian Cristina Gomes; Almeida, Aldênia Mendes Mascena de; Andrade, Eunice Maia de

doi:10.1590/2179-8087.017516

Cited by 10 publications

(5 citation statements)

References 30 publications

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“…In Gilbués, we understand that the extensive soil exposure influences the high C factor more than the vegetation size (Bagarello et al, 2018; Cebecauer & Hofierka, 2008; Schönbrodt et al, 2010). Besides, soil exposure during the dry season facilitates heating, causing soil temperature to rise up to 83°C, which hinders vegetative restoration by fallow (Almeida et al, 2017) and makes restoration more unlikely to occur, in contrast to the successful Spanish experience reported by Navarro‐Hevia, de Araújo, and Mongil‐Manso (2014). Schönbrodt et al (2010) show the high temporal variability of the C factor in China.…”

Section: Discussionmentioning

confidence: 99%

“…The prevalence of the Maner Equation ), whose only parameter is the ratio between a reference basin height and a basin length, over other models in such different spatial scales (from 10 −4 to 10 +3 km 2 ) suggest that relief is the key element to interpret long‐term sediment deposition (directly related to delivery ratio). In fact, terrain steepness influences (and is influenced by) soil formation, runoff formation (De Figueiredo, de Araújo, Medeiros, & Costa, 2016) and velocity, vegetation pattern (Almeida et al, 2017), and, thus, sediment dynamics (Nadal‐Romero & Regüés, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Anthropogenic erosion affects hydro‐sedimentological processes and causes significant impacts on environment and society, among which is soil degradation (Mukundan, Radcliffe, Ritchie, Risse, & McKinley, 2010; Zhao, Kondolf, et al, 2017; Zhao, Mu, et al, 2017), particularly in arid and semiarid regions (Moghadam, Jabarifar, Bagheri, & Shahbazi, 2015; Vaezi, Abbasi, Bussi, & Keesstra, 2016; Vaezi, Abbasi, Bussi, & Keesstra, 2017; Vaezi, Zarrinabadi, & Auerswald, 2017). It also impairs agricultural and forest yield (Almeida, de Araújo, Costa, Almeida, & Andrade, 2017); harms transport infrastructure (Cerdá, 2007; Farias, Medeiros, Navarro‐Hevia, & de Araújo, 2019; MacDonald, Sampson, & Anderson, 2001; Navarro‐Hevia, Farias, de Araújo, Osorio‐Peláez, & Pando, 2016); pollutes (Chaves, Lopes, Maia, Meireles, & Andrade, 2019; Gilley, 2005), and reduces water availability due to reservoir siltation (de Araújo, Güntner, & Bronstert, 2006; Medeiros & de Araújo, 2014; Zhang et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Erosion at hillslope and micro‐basin scales in the Gilbués desertification region, Northeastern Brazil

et al. 2020

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With an area of 6,200 km2, the Gilbués badlands region in the Brazilian drylands is the largest desertification site in the Country. It is located upstream the Boa Esperança Hydroelectric Power Plant and is contiguous to an important Brazilian agricultural area. However, primary quantitative data on erosive processes are scarce or nonexistent. We analyzed on‐site data (2018–2019) concerning small‐scale (hillslope and micro basin) processes: inter‐rill gross erosion, vegetation coverage factor, sediment yield, and sediment delivery ratio. We measured gross erosion in four hillslopes using metal pins; rainfall erosivity using an automatic meteorological station; soil erodibility; and siltation of five check‐dams that control micro basins (101–103 m2) by means of an unmanned aerial vehicle. Gross erosion (102 Mg ha−1 yr−1; 7.5 mm yr−1) is up to 100‐fold the regional mean value and up to 45‐times the tolerable soil‐loss reference value (0.17 mm yr−1), showing that degradation still evolves. Sparse small vegetation directly exposes two thirds of the soil, with a high vegetation factor (0.90). The sediment delivery ratio of the micro basins is 0.88, compatible with low (12%) sediment‐deposition pattern at this scale. The Maner delivery‐ratio model mimicked field observation, which indicates that relief is the key element influencing sediment deposition there. The check‐dam effectiveness considerably decreased after the first decade of operation due to high siltation rates. Although the Gilbués badland occupies only 5% of the basin upstream of the power plant, it contributes 32% of the sediment load to reservoir and dam. This shows the relevance of the badland restoration for the regional sustainability of water and energy supply.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Erosion at hillslope and micro‐basin scales in the Gilbués desertification region, Northeastern Brazil

et al. 2020

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“…This biome presents high seasonality, encompassing a mosaic of scrub vegetation and patches of dry forest, adapted to poor soils, and stressed environmental conditions, such as high temperatures and severe droughts (Leal, da Silva, Tabarelli, & Lacher Jr., 2005; R. M. Santos et al, 2012). However, among the main anthropic threats, slash-and-burn practices for the collection of firewood and charcoal, along with overgrazing, have contributed to the desertification of the Caatinga biome (Almeida et al, 2017;Brazier, Turnbull, Wainwright, & Bol, 2014;Cerdà & Lavee, 1999;Kurz, Coxon, Tunney, & Ryan, 2005).…”

Section: Introductionmentioning

confidence: 99%

Grazing exclusion regulates bacterial community in highly degraded semiarid soils from the Brazilian Caatinga biome

et al. 2021

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Grazing exclusion has been applied as a suitable strategy for soil conservation worldwide, mainly on semiarid soils. However, it is unclear how grazing exclusion reduces the negative effects of overgrazing on the microbial community in the Caatinga biome. In our study, we assessed the bacterial community under three different soil managements in a semiarid region of the Brazilian Caatinga biome, as follows: (a) Native Caatinga vegetation (natural); (b) grazing exclusion (exclusion); and(c) overgrazing (grazed). The bacterial community was assessed through the sequencing of the V4 region of the 16S rRNA gene and analyzed soil chemical and physical properties were correlated with the bacterial community structure. Our results demonstrate that exclusion increases the content of soil carbon and nitrogen, and bacterial diversity, while grazed showed a reduction of 31 and 43% in organic C, compared to exclusion and natural, respectively. However, the changes in bacterial diversity were more expressive in a specific site (No. 1), suggesting that exclusion strategy could be a context-dependent and complex approach to protecting or improving Caatinga soils. Moreover, grazed areas might restrain the potential of bacterial diversity to sustain ecosystem functions since nonbeneficial elements increased in grazed treatments, which presented a negative correlation with the bacterial community. Our study provides novel evidence that high-intensity disturbance by overgrazing could not only reduce soil fertility but it may also restrain bacterial composition, with implications on ecosystem functioning. The Caatinga soil microbiome may be unable to maintain ecosystem services such as plant and animals' development under overgrazing management.

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“…Importantly, it presents a high biodiversity of plants and animals (Albuquerque et al, 2012), including microorganisms (Pereira et al, 2020, which are essential to Caatinga biome maintenance. Although important, this biodiversity is threatened by deforestation, unsuitable soil management, and overgrazing of native vegetation Almeida et al, 2017;. Between 1985 and 2020, an estimated more than 6 million hectares of native Caatinga vegetation were lost, mainly to livestock activities (MapBiomas, 2022), and it has brought adverse effects on plant diversity in this biome (Schulz et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Fungal community structure and functional genes abundance in Brazilian drylands under desertification process

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Fallow Reduces Soil Losses and Increases Carbon Stock in Caatinga

Cited by 10 publications

References 30 publications

Erosion at hillslope and micro‐basin scales in the Gilbués desertification region, Northeastern Brazil

Erosion at hillslope and micro‐basin scales in the Gilbués desertification region, Northeastern Brazil

Grazing exclusion regulates bacterial community in highly degraded semiarid soils from the Brazilian Caatinga biome

Fungal community structure and functional genes abundance in Brazilian drylands under desertification process

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