Emission of CO2 and soil microbial activity in sugarcane management systems

Tavares, Rose Luiza Moraes; Farhate, Camila Viana Vieira; Souza, Zigomar Menezes de; Scala, Newton La; Torres, José Luiz Rodrigues; Campos, Milton César Costa

doi:10.5897/ajar2014.9351

Cited by 13 publications

(4 citation statements)

References 26 publications

(46 reference statements)

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“…Infield F CO2 presented a mean value of 1.19 µmol CO 2 m -2 s -1 , with a minimum of 0.50 µmol CO 2 m -2 s -1 , a maximum of 2.29 µmol CO 2 m -2 s -1 , and a CV of 31.68% (Table 1). These rates are similar to those observed in experiments conducted previously in the same geographic region with sugarcane crops (Brito et al, 2010;Panosso et al, 2011Panosso et al, , 2012Corradi et al, 2013;Bicalho et al, 2014;Tavares et al, 2015). Variations in F CO2 observed in these studies, even performed in areas of the same region, are related to changes in soil attributes for each area, such as soil temperature, soil moisture, soil organic matter, microbial activity, pH, the C/N ratio, phosphorus content, soil bulk density, and soil porosity (Kemmitt et al, 2008;Ngao et al, 2012;Oyonarte et al, 2012;Teixeira et al, 2013a;Karhu et al, 2014;Moitinho et al, 2015).…”

Section: Descriptive Statisticssupporting

confidence: 88%

“…The large amount of crop residue left on the soil surface after harvest in mechanically harvested sugarcane areas have tremendous impact on production processes and biogeochemical cycling of carbon and nitrogen, affecting soil organic matter dynamics, and consequently, GHG emissions (Cerri et al, 2013). In addition to influencing carbon and nitrogen cycles, environmental conditions and soil management practices adopted during sugarcane crop cultivation may result in changes in soil physical, chemical, and biological attributes, directly affecting microbial activity and thus the production of CO 2 , CH 4 , and N 2 O and their exchanges between soil and the atmosphere (Blair, 2000;Sartori et al, 2006;Cerri et al, 2007Cerri et al, , 2013Denmead et al, 2010;Allaire et al, 2012;Ball, 2013;Signor and Cerri, 2013;Signor et al, 2014;Tavares et al, 2015).…”

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confidence: 99%

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Soil Greenhouse Gases: Relations to Soil Attributes in a Sugarcane Production Area

Bicalho

Moitinho

Teixeira

et al. 2017

Soil Science Soc of Amer J

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The production of the main soil greenhouse gases (GHG: carbon dioxide [CO 2 ], methane [CH 4 ,] and nitrous oxide [N 2 O]) is influenced by agricultural practices that cause changes in soil physical, chemical, and biological attributes, directly affecting their emission to the atmosphere. The aim of this study was to investigate the infield soil carbon dioxide emissions (F CO2) and soil CO 2 , methane, and nitrous oxide production potentials (P CO2 , P CH4 , and P N2O , respectively) under laboratory conditions and their relationship to soil attributes in a mechanically harvested sugarcane area. Soil carbon dioxide emissions presented an infield average emission value of 1.19 µmol CO 2 m-2 s-1 , while GHG production in the laboratory was 2.34 µg C-CO 2 g-1 soil d-1 and 0.20 ng N-N 2 O g-1 soil d-1 for P CO2 and P N2O , respectively. No significant production or oxidation was observed for CH 4. Factor analysis showed the formation of two independent processes that explained almost 72% of the total variance observed in the data. The first process was related to F CO2 transport and its relation to soil physical attributes such as microporosity, macroporosity, the C/N ratio, soil moisture, and soil bulk density, showing the dependence between F CO2 and soil porosity. The second process was related to soil CO 2 and N 2 O production potentials under laboratory conditions and their relation to soil chemical attributes such as the sum of bases, pH, and available phosphorus, which affect microbial activity and contribute to GHG production. Although presented as independent, these processes are coupled and occur simultaneously in the soil, in addition to providing information about their variability and showing if the infield emissions are due to gas transport processes or soil carbon levels and their quality.

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Section: Descriptive Statisticssupporting

confidence: 88%

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confidence: 99%

Soil Greenhouse Gases: Relations to Soil Attributes in a Sugarcane Production Area

Bicalho

Moitinho

Teixeira

et al. 2017

Soil Science Soc of Amer J

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“…The equation of the remaining straw decomposition (Tables 3 and 4) allows analyzing the interaction of the material with the environment and defining strategies for soil cover management. In tropical and subtropical regions, the remaining straw act protecting the soil surface, softening the temperature variation of the soil, reducing the evapotranspiration, keeping moisture in the surface zones, providing nutrients to the crops with mineralization of organic matter, and acting in the stabilization of soil aggregates (Torres et al, 2008;Tavares et al, 2015;Bueno e Rodrigues, 2019;Bonetti e Fink, 2020). The parameters of the regression equations and half-life of autumn/winter residues (2020) in soybean (2020/2021) are presented in Table 4.…”

Section: Resultsmentioning

confidence: 99%

Decomposition of the Remaining Straw During Soybean Growing in the Midwestern Paraná, Brazil

Wenneck

Saath

Araújo

et al. 2021

Rev. Agric. Neotrop.

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Crop biomass plays an important role, especially in tropical and subtropical crops that adopt the no-tillage system, whose decomposition is related to material composition and environmental conditions. The objective of this work was to analyze the decomposition of straw remaining from autumn/winter crops in the development of soybean in succession in the Midwest region of Paraná. The experiment was conducted between 2019 and 2021 in a completely randomized design, with eight treatments (spontaneous, black oat, brachiaria, corn, wheat, oilseed radish, corn + brachiaria, and black oat + oilseed radish) and four replications. After autumn/winter cultivation, biomass samples were dried and placed in nylon bags, returning to the original plot during soybean sowing. The decomposition bags were collected in seven periods over 120 days, coinciding with the soybean cycle. The decomposition rate was analyzed by regression. The regression equations and the amount of biomass remaining from the autumn/winter seasons were determinate the half-file and the remaining mass on the soil surface at sowing and at 30, 60, 90, and 120 days after sowing. Biomass production and decomposition rate varied with the season, depending on environmental conditions. Wheat had the lowest decomposition rate with a half-life greater than 100 days. Intercropping crops reduce the decomposition rate.

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“…This traffic of machines tends to increase in areas cultivated with sugarcane. Due to this, developing technologies to determine the impacts from these practices on the physical soil properties is required (Tavares et al, 2015). In this context, controlling the traffic of machines has become a promising alternative to minimize the compaction problem (Kamimura, et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Traffic Control With Autopilot as an Alternative to Decrease Soil Compaction in Sugarcane Areas

Sousa,

Souza,

Poch Claret

et al. 2017

Trop Subtrop Agroecosyst

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<p>Control the machinery traffic through autopilot and use the combined spacing of two rows are possible solutions to mitigate soil compaction problems. The objective of this study was to evaluate traffic control using autopilot in order to soften the problem of soil compaction in mechanically-harvested sugarcane areas. The study was conducted in two experimental areas belonging to Usina Santa Fe, in New Europe, São Paulo, Brazil. The design was a randomized block design, with 3 treatments: T1 = sugarcane planted in single spacing and without autopilot (1.50 m); T2 = sugarcane planted in single line spacing and managed on autopilot; T3 = sugarcane planted under combined spacing of two rows (1.50 × 0.90 m) and managed with autopilot, with 4 replications. Was collected samples in the wheel row (WR) and the seedbed (SB), which was located next to the plant row to, in layers from 0.00 to 0.15 and 0.15-0.30 m. It was observed that the seed bed area showed higher porosity in the treatments with autopilot in the second year of evaluation. There were no differences in pore sizes and shapes between the treatments in the two years studied. The large and complex pores were observed to be reduced in the second evaluation year. </p>

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Emission of CO2 and soil microbial activity in sugarcane management systems

Cited by 13 publications

References 26 publications

Soil Greenhouse Gases: Relations to Soil Attributes in a Sugarcane Production Area

Soil Greenhouse Gases: Relations to Soil Attributes in a Sugarcane Production Area

Decomposition of the Remaining Straw During Soybean Growing in the Midwestern Paraná, Brazil

Traffic Control With Autopilot as an Alternative to Decrease Soil Compaction in Sugarcane Areas

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