Sistemas de manejo e os estoques de carbono e nitrogênio em latossolo de cerrado com a sucessão soja-milho

Nunes, Rafael de Souza; Lopes, André Alves de Castro; Sousa, D. M. G. de; Mendes, I. C.

doi:10.1590/s0100-06832011000400035

Cited by 35 publications

(10 citation statements)

References 46 publications

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“…Sousa et al (2010) verified SOC contents at the 0-to 20-cm depth ranging from 14 to 22 g kg −1 due to differences in the inputs of plant residues as a function of P fertilizer applications in annual cropping systems and pastures. Similar results were also reported by Nunes et al (2011).…”

Section: Soil Phosphorus Soil Organic Carbon and Microbial Indicatorssupporting

confidence: 92%

Interpretation of Microbial Soil Indicators as a Function of Crop Yield and Organic Carbon

Lopes¹,

Sousa

Chaer

et al. 2013

Soil Science Society of America Journal

139

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Section: Soil Phosphorus Soil Organic Carbon and Microbial Indicatorssupporting

confidence: 92%

Interpretation of Microbial Soil Indicators as a Function of Crop Yield and Organic Carbon

Lopes¹,

Sousa

Chaer

et al. 2013

Soil Science Society of America Journal

139

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“…This may be due to the greater root biomass in the 0.00-0.05 m layer under NT system. Other workers (Souza Nunes et al, 2011) have also reported that the NT system resulted in stratification of SOC, while the MP system resulted in a more homogeneous distribution in the 0.00-0.20 m layer.…”

Section: Changes In Soc Distribution In Soil Profilementioning

confidence: 81%

Water-Stable Aggregates and Associated Carbon in a Subtropical Rice Soil Under Variable Tillage

Liu

Chen

et al. 2016

Rev. Bras. Ciênc. Solo

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Tillage systems can influence C sequestration by changing aggregate formation and C distribution within the aggregate. This study was undertaken to explore the impact of no-tillage without straw (NT-S) and with straw (NT+S), and moldboard plow without straw (MP-S) and with straw (MP+S), on soil aggregation and aggregate-associated C after six years of double rice planting in a Hydragric Anthrosol in Guangxi, southwest of China. Soil samples of 0.00-0.05, 0.05-0.20 and 0.20-0.30 m layers were wet-sieved and divided into four aggregate-size classes, >2 mm, 2.00-0.25 mm, 0.25-0.053 and <0.053 mm, respectively, for measuring aggregate associated C and humic and fulvic acids. Results showed that the soil organic carbon (SOC) stock in bulk soil was 40.2-51.1 % higher in the 0.00-0.05 m layer and 11.3-17.0 % lower in the 0.05-0.20 m layer in NT system (NT+S and NT-S) compared to the MP system (MP+S and MP-S), respectively. However, no statistical difference was found across the whole 0.00-0.30 m layer. The NT system increased the proportion of >2 mm aggregate fraction and reduced the proportion of <0.053 mm aggregates in both 0.00-0.05 and 0.05-0.20 m layers. The SOC concentration, SOC stock and humic and fulvic acids within the >0.25 mm macroaggregate fraction also significantly increased in the 0.00-0.5 m layer in NT system. However, those within the 2.00-0.25 mm aggregate fraction were significantly reduced in the 0.05-0.200 m layer under NT system. Straw incorporation increased not only the SOC stock in bulk soil, but also the proportion of macroaggregate, aggregate associated with SOC and humic and fulvic acids concentration within the aggregate. The effect of straw on C sequestration might be dependent on the location of straw incorporation. In conclusion, the NT system increased the total SOC accumulation and humic and fulvic acids within macroaggregates, thus contributing to C sequestration in the 0.00-0.05 m layer.

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“…Thus, the soybean, maize/ wheat succession system contributed to increased levels of TC, especially after reaching the maintenance phase (ANGHINONI, 2007). After the maintenance phase of the NT system was reached (ANGHINONI, 2007), non-disturbance of the system, allied with different strata of the root systems of soybean, maize, and wheat, as well as the potential for C accumulation in the root system of the grasses (NUNES et al, 2011;LOSS et al, 2013), increase the total carbon content. In addition, the difference in the total carbon content found in the 0.00-0.05 m layer between the area of 6 years and 22 years since adoption of the NT is due to the stratification of carbon accumulation, as well as the higher root growth of grass species, such as maize, in the uppermost layers of the soil, as also reported by Costa et al (2009).…”

Section: Resultsmentioning

confidence: 99%

Organic matter and soil aggregation in agricultural systems with different adoption times

Rosset

Lana

Pereira

et al. 2019

SCA

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In conservation management systems, such as no-till (NT), it is important to analyze the pattern of changes in soil quality as a function of the time since adoption of the system. This study evaluated the physical fractions of organic matter and soil aggregation in management systems in areas cultivated with different times since implementation of NT: 6, 14, and 22 successive years of soybean and maize/wheat crops (NT6, NT14, and NT22, respectively); 12 years of no-till with successive years of soybean and maize/wheat crops, and the last 4 years with integration of maize and ruzi grass (Brachiaria ruziziensis) - (NT+B); pasture; and forest. Physical fractionation of organic matter determined the total carbon (TC), particulate organic matter (POM), and mineral organic matter (MOM) by calculating the carbon management index (CMI) and variables related to soil structural stability. Forest and pasture areas showed the highest contents of TC, POM, and MOM, as well as higher stocks of POM and MOM. Among the cultivated areas, higher TC and particulate fractions of organic matter and the best CMI values were observed in the area of NT22. There were changes in aggregation indices, depending on the time since implementation of NT. Areas of NT22, pasture, and forest showed the greatest evolution in C-CO2, indicating increased biological activity, with positive effects on soil structural stability.

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Sistemas de manejo e os estoques de carbono e nitrogênio em latossolo de cerrado com a sucessão soja-milho

Cited by 35 publications

References 46 publications

Interpretation of Microbial Soil Indicators as a Function of Crop Yield and Organic Carbon

Interpretation of Microbial Soil Indicators as a Function of Crop Yield and Organic Carbon

Water-Stable Aggregates and Associated Carbon in a Subtropical Rice Soil Under Variable Tillage

Organic matter and soil aggregation in agricultural systems with different adoption times

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