Soil and crop residue CO2-C emission under tillage systems in sugarcane-producing areas of southern Brazil

Teixeira, Luís Gustavo; Corradi, Mariana Marotti; Fukuda, Adrian; Panosso, Alan Rodrigo; Reicosky, D. C.; Lopes, Afonso; Scala, Newton La

doi:10.1590/s0103-90162013000500007

Cited by 22 publications

(23 citation statements)

References 26 publications

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“…We suppose that the collar of this repetition was placed inadvertently over an accumulation of plant residues buried in the soil. It has been described for other sites that the incorporation of residues increases tillage-induced SR (Alvarez et al, 2001;Dao, 1998;Teixeira et al, 2013). Also in this treatment, precipitation triggered the highest SR of the entire experiment on day 9 since wetting of previously dry soil increases microbial activity and therefore SR in general Kim et al, 2012;Reichstein et al, 2003).…”

Section: Tablesupporting

confidence: 53%

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Fiedler

Buczko

Jurasinski

et al. 2015

Soil and Tillage Research

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Section: Tablesupporting

confidence: 53%

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Fiedler

Buczko

Jurasinski

et al. 2015

Soil and Tillage Research

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“…We believe that the variation in CO 2 emissions during the first 50 DAT was stimulated by cover cropping and tillage and were increased by rainfall events. Several studies indicate that soil tillage increases the oxidation of organic C by releasing large amounts of CO 2 into the atmosphere over a short period of time (Figueiredo, Panosso, Donald, Reicosky, & La Scala, ; Silva‐Olaya, Cerri, La Scala, Dias, & Cerri, ; Teixeira et al., ). At the same time, precipitation events tend to cause changes in soil water content which stimulates microbial activity in addition to infiltration of rainwater causing the expulsion or displacement of air (CO 2 ) from soil porosity, subsequently combining to increase CO 2 emissions (Figueiredo et al., ; Smart & Peñuelas, ).…”

Section: Discussionmentioning

confidence: 99%

Soil tillage and cover crop on soil CO₂ emissions from sugarcane fields

Farhate

Souza

Scala

et al. 2019

Soil Use and Management

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Soil tillage is an agricultural practice that directly affects the global carbon cycle. Our study sought to assess the implications of adopting sunn hemp cover crops with different tillage practices on CO2 emissions for two soil types (clayey and sandy soil) cultivated with sugarcane in Brazil. The experimental design was a split‐plot with randomized blocks, with the main plots being with cover crop or fallow and sub‐plots being under conventional or minimum tillage. Our results indicate that during the first 50 days after soil tillage, the variation in soil CO2 emissions was stimulated by cover crop and soil tillage, while after that, it became dominated by the root respiration of sugarcane plants. We also found that over the first 97 days after the tillage, the clayey soil showed differences between minimum tillage with cover crop and fallow. Conversely, for sandy soil over the first 50 days following, there were differences between the tillage systems under cover cropping. Emissions from sugarcane rows were found to be greater than those from inter‐row positions. We concluded that soils under different textural classes had distinct patterns in terms of soil CO2 emissions. The correct quantification of CO2 emissions during the sugarcane renovation period should prioritize having a short assessment period (~50 days after soil tillage) as well as including measurements at row and inter‐row positions.

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“…Soil tillage practices increase the surface contact between soil and straw (also decrease the size of particles). This, combined with higher aeration and temperature, increases microbial activity (La Scala et al ., ; Silva‐Olaya et al ., ; Teixeira et al ., ).…”

Section: Impacts Of Straw Removal On Soil Greenhouse Gas Emissionsmentioning

confidence: 97%

“…Teixeira et al . () observed that the association between straw mulching and tillage operations increased CO 2 emissions by 36% when compared to similar tillage practices without straw mulching. Soil tillage practices increase the surface contact between soil and straw (also decrease the size of particles).…”

Section: Impacts Of Straw Removal On Soil Greenhouse Gas Emissionsmentioning

confidence: 97%

“…In Brazil, short‐term studies have demonstrated that the removal of sugarcane straw increases soil CO 2 emissions (Corradi et al ., ; Teixeira et al ., ; De Figueiredo et al ., ). Such emissions respond to exponential increases in soil temperature (Davidson et al ., ), which in turn have a remarkable effect on the microbial activity that induces the decomposition of SOM and roots (Silva‐Olaya et al ., ).…”

Section: Impacts Of Straw Removal On Soil Greenhouse Gas Emissionsmentioning

confidence: 99%

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Agronomic and environmental implications of sugarcane straw removal: a major review

et al. 2016

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Large‐scale bioenergy demand has triggered new approaches to straw management in Brazilian sugarcane fields. With the progressive shift from a burned to a nonburned harvest system, most of the straw presently retained on the soil surface has become economically viable feedstock for bioenergy production. The trade‐offs between the need to preserve soil quality and produce more bioenergy have been the subject of intense discussion. This study presents a synthesis of available information on the magnitude of the main impacts of straw removal from sugarcane fields for bioenergy production and therefore represents an easily available resource to guide management decisions on the recommended amount of straw to be maintained on the field to take advantage of the agronomic, environmental, and industrial benefits. Crop residues remaining on sugarcane fields provide numerous ecosystem services including nutrient recycling, soil biodiversity, water storage, carbon accumulation, control of soil erosion, and weed infestation. Furthermore, several studies reported higher sugarcane production under straw retention on the field, while few suggest that straw may jeopardize biomass production in cold regions and under some specific soil conditions. Pest control is among the parameters favored by straw removal, while N2O emissions are increased only if straw is associated with the application of N fertilizer and vinasse. An appropriate recommendation, which is clearly site specific, should be based on a minimum mass of straw on the field to provide those benefits. Overall, this review indicates that most of the agronomic and environmental benefits are achieved when at least 7 Mg ha−1 of dry straw is maintained on the soil surface. However, modeling efforts are of paramount importance to assess the magnitude and rates of straw removal considering the several indicators involved in this complex equation, so that an accurate straw recovery rate could be provided to producers and industry toward greater sustainability.

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Soil and crop residue CO2-C emission under tillage systems in sugarcane-producing areas of southern Brazil

Cited by 22 publications

References 26 publications

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Soil tillage and cover crop on soil CO₂ emissions from sugarcane fields

Agronomic and environmental implications of sugarcane straw removal: a major review

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Soil and crop residue CO2-C emission under tillage systems in sugarcane-producing areas of southern Brazil

Cited by 22 publications

References 26 publications

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Soil respiration after tillage under different fertiliser treatments – implications for modelling and balancing

Soil tillage and cover crop on soil CO2 emissions from sugarcane fields

Agronomic and environmental implications of sugarcane straw removal: a major review

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Soil tillage and cover crop on soil CO₂ emissions from sugarcane fields