Spatial and Temporal Variability of Soil CO<sub>2</sub> Flux in Sugarcane Green Harvest Systems

Tavares, Rose Luiza Moraes; Souza, Zigomar Menezes de; Scala Jr, Newton La; Castioni, Guilherme Adalberto Ferreira; Souza, Gustavo Soares de; Torres, José Luiz Rodrigues

doi:10.1590/18069657rbcs20150252

ABSTRACT

The sugarcane green harvest system, characterized by mechanized harvesting and the absence of crop burning, affects soil quality by increasing crop residue on the soil surface after harvest; thus, it contributes to improving the physical, chemical, and microbiological properties and influences the soil carbon content and CO₂ flux (FCO₂). This study aimed to evaluate the spatial and temporal variability of soil FCO₂ in sugarcane green harvest systems. The experiment was conducted in two areas of sugarcane in São Paulo, Brazil: the first had a 5-year history of sugarcane green harvest (SG-5) and the second had a longer history of 10 years (SG-10). The temporal FCO₂ were evaluated in the dry and rainy periods, and spatial variability in the dry period, and related to soil chemical and physical properties, including organic C porosity, bulk density, soil penetration resistance, mean weight diameter of soil aggregates, clay, P, S, Ca, Mg and Fe. The temporal variability indicated no differences between the dry and rainy periods in SG-10, while in SG-5 soil moisture was increased by 33 % in the rainy period. The spatial variability indicated a different pattern from the temporal one, where FCO₂ in SG-10 was correlated with soil temperature, air-filled pore space, total porosity, soil moisture, and the Ca and Mg contents; in the SG-5 area, FCO₂ was correlated with soil mean weight diameter of soil aggregates and the sulfur content.

CO₂ emission; soil respiration; straw; mechanized harvest; physical properties

INTRODUCTION

The sugarcane green harvest system (characterized by the absence of crop burning, with mechanized harvest and residue deposition on the soil surface, especially leaves and culms), which has replaced the pre-harvest burning method, has increased in use in Brazil since the 1990s due to increased awareness of environmental impacts, such as the increase in gas emissions that cause the greenhouse effect and emissions of particulate matter that have a harmful impact on human health (Arbex et al., 2012Arbex MA, Santos UP, Martins LC, Saldiva PHN, Pereira LAA, Braga ALF. Air pollution and the respiratory system. J Bras Pneumol. 2012;38:643-55. doi:10.1590/S1806-37132012000500015; Sisenando et al., 2012Sisenando HA, Medeiros SRB, Artax P, Saldiva PHN, Hacon SS. Micronucleus frequency in children exposed to biomass burning in the Brazilian Legal Amazon region: a control case study. BMC Oral Health. 2012;12:6-13. doi:10.1186/1472-6831-12-6). The sugarcane green harvest system promotes soil protection by the deposition of larger quantities of straw (average 10 to 30 Mg ha^-1) which provides higher C accumulation in the soil, leading to a positive CO₂ balance (Razafimbelo et al., 2006Razafimbelo T, Barthès B, Larré-Larrouy MC, De Luca EF, Laurent JY, Cerri CC, Feller C. Effect of sugarcane residue management (mulching versus burning) on organic matter in a clayey Oxisol from southern Brazil. Agric Ecosyst Environ. 2006;115:285-89. doi:10.1016/j.agee.2005.12.014) as the C that would be emitted directly by burning remains in the system, it can be incorporated into the soil, favoring microbiota (Panosso et al., 2011Panosso AR, Marques Jr J, Milori DMBP, Ferraudo AS, Barbieri M, Pereira GT, La Scala Jr N. Soil CO2 emission and its relation to soil properties in sugarcane areas under slash-and-burn and green harvest. Soil Till Res. 2011;111:190-96. doi:10.1016/j.still.2010.10.002).

In order to better quantify soil CO₂ emission in agricultural areas, it is imperative to characterize its spatial and temporal variability and how these parameters are affected by management practices (Panosso et al., 2009Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008). Kosugi et al. (2007)Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005 demonstrated the complexity of soil respiration patterns, since spatial variability indicates CO₂ emissions are lower where the soil water content is higher; however, in terms of temporal variability, the opposite effect was found, as soil respiration was higher with increasing soil moisture. The mechanisms controlling the spatio-temporal variability of soil CO₂ efflux in water-limited ecosystems is highly complex (Leon et al., 2014Leon E, Vargas R, Bullock S, Lopez E, Panosso AR, La Scala Jr N. Hot spots, hot moments, and spatio-temporal controls on soil CO2 efflux in a water-limited ecosystem. Soil Biol Biochem. 2014;77:12-21. doi:10.1016/j.soilbio.2014.05.029).

Soil CO₂ emissions from areas under sugarcane cultivation have been studied recently. Brito et al. (2009)Brito LF, Marques Jr J, Pereira GT, Souza ZM, La Scala Jr N. Soil CO2 emission of sugarcane fields as affected by topography. Sci Agric. 2009;66:77-83. doi:10.1590/S0103-90162009000100011 observed that low areas with a convex structure are likely to collect surface run-off and thereby increase the amount of moisture infiltrating the soil microbial population, resulting in higher rates of C mineralization and CO₂ emissions. Panosso et al. (2009)Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008 compared the spatial and temporal variability of soil CO₂ emissions in pre-harvest burning with a seven-year green harvest system and found that the CO₂ emissions were 39 % higher in the burned plot when compared to the green one. Additionally, they showed that, with green management, CO₂ was more homogeneous when spatial and temporal variability were considered.

Soil CO₂ emissions in a sugarcane area affected by tillage events were investigated by Silva-Olaya et al. (2013)Silva-Olaya AM, Cerri CEP, La Scala Jr N, Dias CTS, Cerri CC. Carbon dioxide emissions under different soil tillage systems in mechanically harvested sugarcane. Environ Res Lett. 2013;8:1-8. doi:10.1088/1748-9326/8/1/015014, and they showed that conventional operations (consisting of two heavy offset disk harrowing operations and a subsoiling operation) cause more emissions of CO₂ to the atmosphere when compared with minimum tillage (chemically eliminating sugarcane ratoon followed by a subsoiling operation with row planting) and reduced tillage (involving two phases of mechanical elimination of the ratoon and two subsoiling operations). They suggested that the impact of minimum and reduced tillage on organic C loss was lower than that observed for conventional operation. A study by Corradi et al. (2013)Corradi MM, Panosso AR, Martin Filho MV, La Scala Jr N. Crop residues on short-term CO2 emissions in sugarcane production areas. Eng Agríc. 2013;33:699-708. doi:10.1590/S0100-69162013000400009 on green cane harvest showed higher CO₂ emissions with no crop residues on the soil surface (bare soil) compared to soil covered with straw. The authors concluded that the conservation of sugarcane crop residues on the soil after harvest could have an impact on soil C conservation.

Overall, studies on soil CO₂ fluxes in sugarcane areas have involved the comparison of green and burned cane, or different soil tillage practices, but few studies have analyzed the effect of green harvest, taking into account the time after conversion. Our hypothesis is that there exists a dynamic change in the spatial and temporal patterns of soil CO₂ emissions once the sugarcane harvest system is converted from burned to green, and that this depends on crop residue input and the compaction of the soil due to mechanized operations over time after conversion. Following this, the objective of this work was to evaluate the spatial and temporal variability of CO₂ emissions in sugarcane green harvest systems five and 10 years after conversion from pre-harvest burning.

MATERIALS AND METHODS

The study was conducted in two sugarcane areas belonging to a sugar-alcohol mill, located in the northeast of São Paulo State, southeastern Brazil, with the coordinates 21° 19’ 8” S and 48° 7’ 24” W (Figure 1). The climate of the region is classified as B₂rB’4a’ according to the Thornthwaite climate classification, and the topography in the area is flat and undulating.

Figure 1
Experiment location and area topography with the sampling grids settled on each one. 5-year sugarcane green harvest system (SG-5) and 10-year sugarcane green harvest system (SG-10).

Description of the experimental areas

The evaluated areas were managed according to the green harvest system, with different implementation history after conversion from pre-harvest burning: the first had a five-year history of sugarcane green harvest (SG-5) and the second had a 10-year history (SG-10). Both areas had soil classified as Latossolo Vermelho Eutrófico (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras, JF, Coelho, MR, Almeida JA, Cunha TJF, Oliveira JB. Sistema brasileiro de classificação de solos. 3ª. ed. Brasília, DF: Embrapa; 2013.), a Haplustox (USDA, 2014United States Department of Agriculture – USDA. Keys to Soil Taxonomy. 20th ed. Washington, DC: Natural Resources Conservation Service; 2014.).

After the conversion to a green harvest system, SG-5 had not undergone crop renovation, but in SG-10, renovation occurred six years after implementation and was composed of, initially, mechanical ratoon elimination from the previous crop and subsoiling at a depth of 0.45 m in the planting furrows. Soon after these operations, 2 Mg ha^-1 of dolomitic limestone was applied. For planting fertilization, 480 kg ha^-1 of the NPK formulation (10-25-20) was used. A mean of 100 m³ ha^-1 of bagasse and 200 kg ha^-1 of ammonium nitrate was applied in the area.

In each experimental area, 1 ha was delimited where the sampling grid was located with 81 sampling points spaced at 1, 2, and 10 m intervals, in a star shape, with the points directed to different angles to aid in the study of the anisotropy of spatial variability (Figure 1). The points were georeferenced with the help of a total station (Leica^® model TC 305) and DGPS (L1/L2 Hiper Lite Plus).

Climatic data

Data on air temperature, rainfall and air humidity are shown in figure 2a; soil temperature is presented in figure 2b. There was no rainfall during the experimental period.

Figure 2
Air temperature, air humidity, and rainfall during the experimental period (a), and soil temperature (b).

Evaluation of soil CO2 flux

The evaluation of CO₂ was simultaneously performed in both areas using two chambers at all sampling grid points, during the 2011 dry and 2012 rainy periods, in the morning (7-11 a.m.), using soil chambers manufactured by LI-COR^® (Nebraska, USA, model LI-8100). The instrument is a closed system, with an internal volume of 991 cm³ and a contact area with the soil of 71.6 cm², placed on PVC collars (0.10 m diameter) that were previously inserted (two days before) into the soil at a depth of 0.03 m, only once at each point and site. Soil temperature and moisture were evaluated simultaneously with measurements of the CO₂ concentration by a temperature sensor coupled to the LI-8100 system; for the evaluation of soil water content, TDR-Campbell^® equipment was used.

Evaluation of soil properties

Soil penetration resistance test and soil sampling for analysis were performed at the sampling grid points. For the penetration resistance test (Stolf, 1991Stolf R. Teoria, teste experimental de fórmulas de transformação dos dados de penetrômetro de impacto em resistência do solo. Rev Bras Cienc Solo. 1991;15:229-35.), an impact penetrometer (model IAA/Planalsucar) was used, with a 30° cone angle.

Undeformed samples were collected to analyze soil porosity and bulk density according to the guidelines of Brazilian Agricultural Research Corporation (Claessen, 1997Claessen MEC, organizador. Manual de métodos de análise de solo. 2a ed. rev. atual. Rio de Janeiro: Embrapa Solos; 1997. (Documentos, 1). Disponível em: https://www.agencia.cnptia.embrapa.br/Repositorio/Manual+de+Metodos_000fzvhotqk02wx5ok0q43a0ram31wtr.pdf.
https://www.agencia.cnptia.embrapa.br/Re... ). Deformed soil samples were collected from the soil surface (0.00-0.10 m depth) and exposed to the air for 24 h, then placed in a sieve set of 6.35 and 2 mm.

Soil aggregates were obtained from samples retained by the 2 mm sieve and were analyzed for mean weight diameter (MWD) of soil aggregates according Kemper and Chepil (1965)Kemper WD, Chepil WS. Size distribution of aggregates. In: Black CA, editor. Methods of soil analysis: physical and mineralogical properties, including statistics of measurement and sampling, Madison: Soil Science Society of America; 1965. Pt 1. p.499-510., while those that went through the sieve were used to evaluate the organic C content (Nelson and Sommers, 1996Nelson DW, Sommer LE. Total carbon, organic carbon and organic matter. In: Page RH, Kenny DR, editors. Methods of soil analysis; chemical and microbiological properties. Madison: Soil Science Society of America; 1996. Pt.2. p. 961-1010.) as well as pH, P, S, Ca, Mg and Fe (Raij et al., 2001Raij Bvan, Andrade JC, Cantarella H, Quaggio JA. Análise química para avaliação da fertilidade de solos tropicais. Campinas: Instituto Agronômico de Campinas; 2001.).

Statistical analyses

Data analysis was performed on the descriptive statistics by calculating the mean, standard deviation, maximum and minimum values, and coefficient of variation. Means were compared by the t-test at 5 % probability. The hypothesis of data normality was verified by the Kolmogorov-Smirnov test, using SAS software (version 2). Analyses of variance (repeated measures over time) and linear regression were used for the analysis of temporal variability. Spatial dependence was assessed via adjustments of semivariograms (Vieira, 2000Vieira SR. Geoestatística em estudos de variabilidade especial do solo. Tópicos Cienc Solo. 2000;1:1-53.) based on the stationarity assumption of the intrinsic hypothesis, which is estimated by:

where N(h) is the pair number of the observation points Z(xi) and Z(xi + h) is separated by distance h. The variogram is represented by the graph ŷ(h) versus h. From the adjustment of a mathematical model to the ŷ(h) calculated values, the coefficients of the theoretical model for the variogram were estimated (nugget effect, C₀; sill, C₀+C₁; and range, a). To analyze the spatial dependence degree of the studied properties, the classification used was described by Cambardella et al. (1994)Cambardella CA, Moorman TB, Novak JM, Parkin TB, Karlen DL, Turco RF, Konopka AE. Field-scale variability of soil properties in Central Iowa Soils. Soil Sci Soc Am J. 1994;58:1501-11. doi:10.2136/sssaj1994.03615995005800050033x, who consider a strong spatial dependence for semivariograms with a nugget effect <25 % of the sill; moderate between 25 and 75 %; and weak >75 %.

RESULTS AND DISCUSSION

Temporal variability

The greatest soil FCO₂ was observed in the rainy period, with 2.33 and 2.89 µmol m^-2 s^-1 CO₂ in SG-5 and SG-10, respectively, in comparison with the dry period, at 1.19 and 2.62 µmol m^-2 s^-1 CO₂; a significant difference (p<0.05) was found only for SG-5, with a 33 % increase in the rainy period (Table 1). Other studies have demonstrated greater soil CO₂ emissions in the rainy period (Xu and Qi, 2001Xu M, Qi Y. Soil surface CO2 efflux and its spatial and temporal variations in a young ponderosa pine plantation in northern California. Global Change Biol. 2001;7:667-77. doi:10.1046/j.1354-1013.2001.00435.x; Epron et al., 2004Epron D, Nouvellon Y, Roupsard O, Mouvondy W, Mabiala A, SaintAndre L, Joffre R, Jourdan J, Bonnefond JM, Berbigier P, Hamel O. Spatial and temporal variations of soil respiration in a eucalyptus plantation in Congo. For Ecol Manage. 2004;202:149-60. doi:10.1016/j.foreco.2004.07.019; Kosugi et al., 2007Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005; Song et al., 2013)Song Z, Yuan H, Kimberley MO, Jiang H, Zhou G, Wang H. Soil CO2 flux dynamics in the two main plantation forest types in subtropical China. Sci Total Environ. 2013;444:363-8. doi:10.1016/j.scitotenv.2012.12.006; this is mainly related to greater microbial activity promoted by soil moisture and, or, root activity during plant growth and development. Soil FCO₂ in SG-10 was more consistent over time and an increase associated with the rainy period was not observed as it was in SG-5 (Figure 3).

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Table 1
Descriptive statistics for CO2 emission, soil moisture and air-filled pore space in 5- and 10-year sugarcane green harvest areas (SG-5 and SG-10, respectively) in the dry and rainy periods, and soil temperature in the dry and rainy periods (n=81)

Figure 3
CO2 emission and soil moisture under 5- and 10-year sugarcane green harvest systems, in 2011/2012, in São Paulo State Northeast/Brazil.

Soil moisture was higher in the rainy period than in the dry period in both SG-5 (38.41 and 11.16 %) and SG-10 (29.71 and 10.17 %), with a significant difference between periods (p<0.05); however, differences in soil moisture were not significant between areas (p>0.05) (Table 1). The air-filled pore space (AFPS), calculated from the moisture data, was higher in the dry period, reaching 44.40 and 43.24 % in SG-5 and SG-10, respectively, due to lower water availability during this period. In the rainy period, because of rainfall, pores are filled with water, presenting lower AFPS, i.e. 17.07 % for SG-5 and 26.07 % for SG-10.

Soil temperature showed the same tendency as soil moisture and AFPS (Table 1), and temperature was significantly (p<0.05) higher in the rainy period (23.39 °C) than in the dry period (18.90 °C). This happens because summer in the region is characterized by a higher rainfall frequency and temperature, what stimulates soil microbial activity since the ideal conditions for the decomposition process are around 30 °C and 60-80 % soil moisture (Kononova, 1975Kononova MM. Humus of virgin and cultivated soils. In: Gieseking JE, editor. Soil components. Berlin: Springer; 1975. p.475-526.), thus affecting FCO₂.

Thus, in SG-5, the FCO₂ increase in the rainy period, in comparison with the dry period (Figure 3), was followed by variations in soil moisture, indicating the direct influence of soil moisture on FCO₂. This was confirmed by the calculation of the determination coefficient between both factors (CO₂ and Sm), providing R² = 0.73 (Figure 4d). Other studies also identified the influence of soil moisture on FCO₂ (Kosugi et al., 2007Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005; Panosso et al., 2009Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008; Liu et al., 2011Liu J, Jiang P, Wang H, Zhou G, Wu J, Yang F, Qian X. Seasonal soil CO2 efflux dynamics after land use change from a natural forest to Moso bamboo plantations in sub-tropical China. For Ecol Manage. 2011;262:1131-7. doi:10.1016/j.foreco.2011.06.015). This effect can be explained by the fact that the rainy period is characterized by more soil moisture and higher temperatures, which are better conditions for microbial activity. As a consequence of this process, the CO₂ flux is greater (Mendonza et al., 2000Mendonza HNS, Lima E, Anjos LHC, Silva LA, Ceddia MB, Antunes MWV. Propriedades químicas e biológicas de solo de tabuleiro cultivado com cana-de-açúcar com e sem queima da palhada. Rev Bras Cienc Solo. 2000;24:201-7. doi:10.1590/S0100-06832000000100022; Zornoza et al., 2007Zornoza R, Guerreo C, Mataix-Solera J, Arcenegui V, Garcia-Orenes F, Mataix-Beneyto J. Assessing the effects of air-drying and rewetting pre-treatment on soil microbial biomass, basal respiration, metabolic quotient and soluble carbon under Mediterranean conditions. Eur J Soil Biol. 2007;43:120-9. doi:10.1016/j.ejsobi.2006.11.004).

Figure 4
Regression analysis of CO2 emission according to air temperature (a), soil temperature (b), air humidity (c), soil moisture (d), air-filled pore space (e), and relationship between soil moisture and temperature (f).

The soil temperature also presented a significant correlation with FCO₂ in SG-5, with R² = 0.80 (Figure 4b). Nevertheless, the evaluation of soil temperature must be carefully analyzed, since temperature was influenced by soil moisture in both SG-5 (R² = 0.85) and SG-10 (R² = 0.90) (Figure 4f). This was also detected in study of Leon et al. (2014)Leon E, Vargas R, Bullock S, Lopez E, Panosso AR, La Scala Jr N. Hot spots, hot moments, and spatio-temporal controls on soil CO2 efflux in a water-limited ecosystem. Soil Biol Biochem. 2014;77:12-21. doi:10.1016/j.soilbio.2014.05.029 on temporal and spatial variation of soil CO₂ efflux in a water-limited Mediterranean ecosystem; they found that the changes in soil volumetric water content influenced the relationship between CO₂ efflux and soil temperature. Epron et al. (2004)Epron D, Nouvellon Y, Roupsard O, Mouvondy W, Mabiala A, SaintAndre L, Joffre R, Jourdan J, Bonnefond JM, Berbigier P, Hamel O. Spatial and temporal variations of soil respiration in a eucalyptus plantation in Congo. For Ecol Manage. 2004;202:149-60. doi:10.1016/j.foreco.2004.07.019, when studying CO₂ emissions from soil cultivated with eucalyptus, concluded that the bivariate model, including soil temperature and moisture, did not explain the temporal variations in CO₂ emission; the univariate model, with the use of soil moisture, was more efficient.

Besides soil moisture and temperature, FCO₂ in SG-5 presented an indirect relationship with air-filled pore space of R² = 0.73 to SG-5 and R² = 0.51 to SG-10 (Figure 4e) and this may be related to the stimulation of microbial activity, which was promoted by higher soil moisture and had a great influence on FCO₂ (Davidson and Swank, 1986Davidson EA, Swank WT. Environmental parameters regulating gaseous nitrogen losses from two forested ecosystems via nitrification and denitrification. Appl Environ Microbiol. 1986;52:1287-92. doi:10.1111/j.1750-3841.2007.00346.x), especially in the rainy period, when AFPS was lower than in the dry period.

Regarding SG-10, the temporal variability of FCO₂ was not significant (p>0.05) (Table 1, Figure 3). Furthermore, the seasonal factors obtained in this study, such as temperature, soil moisture, air humidity and AFPS did not affect FCO₂ in SG-10. These results indicate that FCO₂ in SG-10 was more stable than in SG-5, with no influence of soil temperature and moisture which, according to some studies, are considered to be the main factors affecting the temporal variability of FCO₂ (La Scala Jr et al., 2000aLa Scala Jr N, Marques Jr J, Pereira, GT, Corá JE. Short-term temporal changes in the spatial variability model of CO2 emissions from a Brazilian bare soil. Soil Biol Biochem. 2000a;32:1459-62. doi:10.1590/S0006-87052010000500004; Xu and Qi, 2001Xu M, Qi Y. Soil surface CO2 efflux and its spatial and temporal variations in a young ponderosa pine plantation in northern California. Global Change Biol. 2001;7:667-77. doi:10.1046/j.1354-1013.2001.00435.x; Epron et al., 2004Epron D, Nouvellon Y, Roupsard O, Mouvondy W, Mabiala A, SaintAndre L, Joffre R, Jourdan J, Bonnefond JM, Berbigier P, Hamel O. Spatial and temporal variations of soil respiration in a eucalyptus plantation in Congo. For Ecol Manage. 2004;202:149-60. doi:10.1016/j.foreco.2004.07.019; Panosso et al., 2009)Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008.

The greater quantity of straw and its longer permanence in SG-10 possibly promoted higher stability in soil FCO₂ during the evaluated period (dry and rainy). This occurred because the straw, apart from improving the physical aspects of soil, stimulates soil microbial activity due to an increased substrate supply, promoting greater FCO₂ and releasing organic compounds into the soil.

Spatial variability

Soil FCO₂ in the SG-5 and SG-10 systems ranged from 1.19 to 2.89 µmol m^-2 s^-1 CO₂ (Table 1), similar values to those found by Panosso et al. (2009)Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008, who showed a flux of 1.81-2.67 µmol m^-2 s^-1 CO₂ from soil submitted to a seven-year sugarcane green harvest system in the same region. La Scala Jr et al. (2000a) obtained a flux of 1.46-2.80 µmol m^-2 s^-1 CO₂ from a bare Oxisol.

The descriptive analysis for FCO₂ indicated higher flux (p<0.05) in SG-10 (2.33 and 2.89 µmol m^-2 s^-1 CO₂ in the dry and rainy periods, respectively) in comparison with SG-5 (1.19 and 2.62 µmol m^-2 s^-1 CO₂). The amount of straw in SG-10 possibly influenced FCO₂ as the presence of residue on the soil surface provides the ideal conditions of temperature and moisture for the decomposition process (Medeiros et al., 2011)Medeiros JC, Silva AP, Cerri CEP, Fracetto FJC. Linking physical quality and CO2 emission under long-term no-till and conventional-till in a subtropical soil in Brazil. Plant Soil. 2011;338:5-15. doi:10.1007/s11104-010-0420-4. Furthermore, it improves the soil physical structure, promoting greater gas flow in the soil and stimulating microbial activity (Carbonell-Bojollo et al., 2012)Carbonell-Bojollo R, Torres MAR-R, Rodriguez-Lizana A, Ordóñez-Fernández R. Influence of soil and climate conditions on CO2 emissions from agricultural soils. Water Air Soil Pollut. 2012;223:3425-35. doi:10.1007/s11270-012-1121-9.

The SG-10 area, with a longer history of the sugarcane green harvest system, had greater amounts of straw on the soil surface, which represents a larger amount of substrate and energy supply for microorganisms and, consequently, higher CO₂ release. In other studies, straw was found to be fundamental to FCO₂ from soils cultivated with pine (Fang et al., 1998Fang C, Moncrieff JB, Gholz HL, Clark KL. Soil CO2 efflux and its spatial variation in a Florida slash pine plantation. Plant Soil. 1998;205:135-46. doi:10.1023/A:1004304309827) and eucalyptus (Epron et al., 2004Epron D, Nouvellon Y, Roupsard O, Mouvondy W, Mabiala A, SaintAndre L, Joffre R, Jourdan J, Bonnefond JM, Berbigier P, Hamel O. Spatial and temporal variations of soil respiration in a eucalyptus plantation in Congo. For Ecol Manage. 2004;202:149-60. doi:10.1016/j.foreco.2004.07.019), where greater emissions were found in regions of more plant residue on the soil surface. Medeiros et al. (2011)Medeiros JC, Silva AP, Cerri CEP, Fracetto FJC. Linking physical quality and CO2 emission under long-term no-till and conventional-till in a subtropical soil in Brazil. Plant Soil. 2011;338:5-15. doi:10.1007/s11104-010-0420-4 also detected greater FCO₂ from soil covered with straw (no tillage) in comparison with soil submitted to conventional tillage, and related the effect to an increased stock of organic carbon in soils under no tillage regimes. Lenka and Lal (2013)Lenka NK, Lal R. Soil aggregation and greenhouse gas flux after 15 years of wheat straw and fertilizer management in a no-till system. Soil Till Res. 2013;126:78-89. doi:10.1016/j.still.2012.08.011 also found greater FCO₂ from soil with more wheat straw (16 Mg ha^-1) in comparison with areas with 0 and 8 Mg ha^-1.

Soil porosity is a physical attribute related to gas transportation; high porosity enables O₂ flow (Xu and Qi, 2001Xu M, Qi Y. Soil surface CO2 efflux and its spatial and temporal variations in a young ponderosa pine plantation in northern California. Global Change Biol. 2001;7:667-77. doi:10.1046/j.1354-1013.2001.00435.x; Kosugi et al., 2007Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005; Brito et al., 2009Brito LF, Marques Jr J, Pereira GT, Souza ZM, La Scala Jr N. Soil CO2 emission of sugarcane fields as affected by topography. Sci Agric. 2009;66:77-83. doi:10.1590/S0103-90162009000100011), higher microbial activity and therefore greater soil FCO₂ (Fang et al., 1998Fang C, Moncrieff JB, Gholz HL, Clark KL. Soil CO2 efflux and its spatial variation in a Florida slash pine plantation. Plant Soil. 1998;205:135-46. doi:10.1023/A:1004304309827). Although SG-5 and SG-10 showed similar soil total porosity (p>0.05), the macroporosity was greater (p<0.05) in SG-10 (23.48 m³ m^-3) than in SG-5 (18.42 m³ m^-3) (Table 2), indicating better gas transportation in SG-10. This was confirmed by the values of soil penetration resistance, which were lower in SG-10 (3.45 MPa) than in SG-5 (5.04 MPa) (Table 2). A similar result was described by Brito et al. (2009)Brito LF, Marques Jr J, Pereira GT, Souza ZM, La Scala Jr N. Soil CO2 emission of sugarcane fields as affected by topography. Sci Agric. 2009;66:77-83. doi:10.1590/S0103-90162009000100011, who studied CO₂ emissions from soil cultivated with sugarcane in different topographic positions, demonstrating higher emissions in areas with greater soil macroporosity.

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Table 2
Descriptive statistics for soil chemical and physical properties evaluated in sugarcane green harvest areas after 5 (SG-5) and 10 years (SG-10) of implementation

In SG-10, FCO₂ in the dry and rainy periods presented a significant correlation (p<0.05) with the evaluated properties; furthermore, in the dry period, FCO₂ was positively correlated with soil temperature (0.23) and negatively with soil moisture (-0.29) (Table 3). A correlation between CO₂ and St was also described by Lenka and Lal (2013)Lenka NK, Lal R. Soil aggregation and greenhouse gas flux after 15 years of wheat straw and fertilizer management in a no-till system. Soil Till Res. 2013;126:78-89. doi:10.1016/j.still.2012.08.011.

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Table 3
Coefficients of the linear correlations between CO2 emissions and soil properties in sugarcane green harvest areas after 5 (SG-5) and 10 years (SG-10) of implementation in the dry (DryP) and rainy (RainP) periods

In the rainy period, FCO₂ in SG-10 presented a significant positive correlation with AFPS, total porosity, and Ca and Mg contents. Xu and Qi (2011) also found a positive correlation between FCO₂ and Mg, which, according to the authors, is related to microbial activity. The contents of Mg and Ca presented a positive correlation with CO₂ in SG-10, which influenced the soil pH, therefore improving microorganism performance during the decomposition process.

Analysis of the correlation between FCO₂ and soil properties in SG-5 showed that it was significant for the dry period (Table 3); it was positive for MWD (0.26) and S (0.30). Such a correlation was also described by Mangalassery et al. (2013)Mangalassery S, Sjögersten, S, Sparkes DL, Sturrock CJ, Mooney SJ. The effect of soil aggregate size on pore structure and its consequence on emission of greenhouse gases. Soil Till Res. 2013;132:39-46. doi:10.1016/j.still.2013.05.003, who found greater FCO₂ from soil with more macroaggregates. Similar results were obtained by Brito et al. (2009)Brito LF, Marques Jr J, Pereira GT, Souza ZM, La Scala Jr N. Soil CO2 emission of sugarcane fields as affected by topography. Sci Agric. 2009;66:77-83. doi:10.1590/S0103-90162009000100011 and Lenka and Lal (2013)Lenka NK, Lal R. Soil aggregation and greenhouse gas flux after 15 years of wheat straw and fertilizer management in a no-till system. Soil Till Res. 2013;126:78-89. doi:10.1016/j.still.2012.08.011, who concluded that C in soil aggregates would be available to microbial attack, thus emitting CO₂. Regarding the relationship between CO₂ and S, it is possible that it is associated with a specific group of soil microorganisms called chemoautotrophs, which use CO₂ as an energy source in the S oxidation process (Alexander, 1999Alexander DB. Bacteria and Archaea. In: Sylvia DM, Fuhrmann JJ, Hartel PG, Zuberer DA, editors. Principles and applications of soil microbiology. New Jersey: Prentice Hall; 1999. p.44-71.). In SG-5, the sulfur concentration was significantly (p<0.05) higher (7.84 mg dm^-3) than in SG-10 (0.48 mg dm^-3), which possibly explains the correlation between CO₂ and sulfur in SG-5.

The relationship between FCO₂ and other soil properties obtained by spatial variability was different from the temporal variability; according to Xu and Qi (2001)Xu M, Qi Y. Soil surface CO2 efflux and its spatial and temporal variations in a young ponderosa pine plantation in northern California. Global Change Biol. 2001;7:667-77. doi:10.1046/j.1354-1013.2001.00435.x, spatial variability does not always agree with the temporal pattern. In this study, in other words, some properties such as soil moisture and temperature, as well as air humidity and temperature, explained the temporal variability of FCO₂ in SG-5, but did not influence FCO₂ in SG-10. Nevertheless, the spatial variability analysis showed that soil temperature and moisture influenced FCO₂ only in SG-10.

In some studies, soil FCO₂ was positively correlated with the organic carbon (OC) content (La Scala Jr et al., 2000bLa Scala Jr N, Marques Jr J, Pereira, GT, Corá JE. Carbon dioxide emission related to chemical properties of a tropical bare soil. Soil Biol Biochem. 2000b;32:1469-73. doi:10.1016/S0038-0717(00)00053-5; Medeiros et al., 2011Medeiros JC, Silva AP, Cerri CEP, Fracetto FJC. Linking physical quality and CO2 emission under long-term no-till and conventional-till in a subtropical soil in Brazil. Plant Soil. 2011;338:5-15. doi:10.1007/s11104-010-0420-4; Lenka and Lal, 2013Lenka NK, Lal R. Soil aggregation and greenhouse gas flux after 15 years of wheat straw and fertilizer management in a no-till system. Soil Till Res. 2013;126:78-89. doi:10.1016/j.still.2012.08.011). In this study, however, SG-10 presented a lower OC content and greater FCO₂. The high microbial activity in that area possibly reduced the OC content, as an increase in cycles of organic matter decomposition by soil microorganisms results in a lower OC content, although it can be more protected and stabilized in microaggregates (Lenka and Lal, 2013Lenka NK, Lal R. Soil aggregation and greenhouse gas flux after 15 years of wheat straw and fertilizer management in a no-till system. Soil Till Res. 2013;126:78-89. doi:10.1016/j.still.2012.08.011). Furthermore, Fang et al. (1998)Fang C, Moncrieff JB, Gholz HL, Clark KL. Soil CO2 efflux and its spatial variation in a Florida slash pine plantation. Plant Soil. 1998;205:135-46. doi:10.1023/A:1004304309827 detected greater CO₂ emissions in regions with a lower OC content in soil cultivated with pine. According to these authors, the decomposition of soil organic matter results in less organic matter being left in the soil.

The experimental variograms showed the spatial dependence pattern of FCO₂ for both areas (Figure 5). In SG-5, the spherical model was adjusted to the semivariograms in both the dry and rainy periods, indicating high spatial continuity of FCO₂ (Isaaks and Srivastava, 1989Isaaks EH, Srivastava RM. An introduction to applied geostatistics. New York: Oxford University; 1989.). A spherical model for FCO₂ was also adjusted to semivariograms in studies performed by Kosugi et al. (2007)Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005 and La Scala Jr et al. (2000a)La Scala Jr N, Marques Jr J, Pereira, GT, Corá JE. Short-term temporal changes in the spatial variability model of CO2 emissions from a Brazilian bare soil. Soil Biol Biochem. 2000a;32:1459-62. doi:10.1590/S0006-87052010000500004. Furthermore, the degree of spatial dependence was moderate, which was also found by Panosso et al. (2009)Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008 and La Scala Jr et al. (2000b)La Scala Jr N, Marques Jr J, Pereira, GT, Corá JE. Carbon dioxide emission related to chemical properties of a tropical bare soil. Soil Biol Biochem. 2000b;32:1469-73. doi:10.1016/S0038-0717(00)00053-5. Although studies have reported differences of range in CO₂ spatial variability during the dry and rainy periods (Kosugi et al., 2007Kosugi Y, Mitani T, Itoh M, Noguchi S, Tani M, Matsuo N, Takanashi S, Ohkubo S, Nik AR. Spatial and temporal variation in soil respiration in a Southeast Asian tropical rainforest. Agric For Meteorol. 2007;147:35-47. doi:10.1016/j.agrformet.2007.06.005; Ohashi and Gyokusen, 2007Ohashi M, Gyokusen K. Temporal change in spatial variability of soil respiration on slope of Japanese cedar (Cryptomeria japonica D. Don) forest. Soil Biol Biochem. 2007;39:1130-8. doi:10.1016/j.soilbio.2006.12.021), in this study, the range was of 25 m for both periods.

Figure 5
Experimental variograms for soil CO2 emission in sugarcane green harvest areas after 5- and 10-years of implementation during dry (Dry P) and wet (Rainy P) periods. Model (C0-C0+C1-r). C0: nugget effect; C0 +C1: sill; r: range.

In SG-10, there was an absence of spatial dependence (nugget effect), and it was not possible to adjust any theoretical model to explain the FCO₂ variation. This means that the values of FCO₂ showed a random spatial distribution, or that the space between the points of the grid was not sufficient to detect the spatial dependence of FCO₂ in SG-10. This effect was found in similar studies on CO₂ flux in soil under green cane (Panosso et al., 2009Panosso AR, Marques Jr J, Pereira GT, La Scala Jr N. Spatial and temporal variability of soil CO2 emission in a sugarcane area under green and slash-and-burn managements. Soil Till Res. 2009;105:275-82. doi:10.1590/S0103-90162013000300008), burned cane (Panosso et al., 2008Panosso AR, Pereira GT, Marques Jr J, La Scala Jr N. Variabilidade espacial da emissão de CO2 em Latossolos sob cultivo de cana-de-açúcar em diferentes sistemas de manejo. Eng Agríc. 2008;28:227-36. doi:10.1590/S0100-69162008000200003) and bare soil (La Scala Jr et al., 2000aLa Scala Jr N, Marques Jr J, Pereira, GT, Corá JE. Short-term temporal changes in the spatial variability model of CO2 emissions from a Brazilian bare soil. Soil Biol Biochem. 2000a;32:1459-62. doi:10.1590/S0006-87052010000500004).

CONCLUSIONS

Soil CO₂ flux (FCO₂) presented differences in spatial and temporal variability patterns dependent on the period of conversion from burned to green cane harvest.

FCO₂ in SG-10 was steadier over time during the dry to rainy period, while in SG-5, fluxes were more affected by precipitation events due to changes in soil moisture.

Spatial variability indicated that FCO₂ in SG-10 was linearly correlated with soil temperature, air-filled pore space, total porosity, Ca and Mg contents, and negatively correlated with soil moisture. On the other hand, in SG-5, FCO₂ was correlated with the mean weight diameter of soil aggregates and sulfur content.

ACKNOWLEDGMENTS

The authors thank FAPESP/SP for financial support and the São Martinho ethanol mill for providing the study area.

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Publication Dates

Publication in this collection
2016

History

Received
10 Aug 2015
Accepted
12 Nov 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Alexander DB. Bacteria and Archaea. In: Sylvia DM, Fuhrmann JJ, Hartel PG, Zuberer DA, editors. Principles and applications of soil microbiology. New Jersey: Prentice Hall; 1999. p.44-71.

[2] Arbex MA, Santos UP, Martins LC, Saldiva PHN, Pereira LAA, Braga ALF. Air pollution and the respiratory system. J Bras Pneumol. 2012;38:643-55. doi:10.1590/S1806-37132012000500015

[3] Brito LF, Marques Jr J, Pereira GT, Souza ZM, La Scala Jr N. Soil CO₂ emission of sugarcane fields as affected by topography. Sci Agric. 2009;66:77-83. doi:10.1590/S0103-90162009000100011

[4] Cambardella CA, Moorman TB, Novak JM, Parkin TB, Karlen DL, Turco RF, Konopka AE. Field-scale variability of soil properties in Central Iowa Soils. Soil Sci Soc Am J. 1994;58:1501-11. doi:10.2136/sssaj1994.03615995005800050033x

[5] Carbonell-Bojollo R, Torres MAR-R, Rodriguez-Lizana A, Ordóñez-Fernández R. Influence of soil and climate conditions on CO₂ emissions from agricultural soils. Water Air Soil Pollut. 2012;223:3425-35. doi:10.1007/s11270-012-1121-9

[6] Claessen MEC, organizador. Manual de métodos de análise de solo. 2a ed. rev. atual. Rio de Janeiro: Embrapa Solos; 1997. (Documentos, 1). Disponível em: https://www.agencia.cnptia.embrapa.br/Repositorio/Manual+de+Metodos_000fzvhotqk02wx5ok0q43a0ram31wtr.pdf
» https://www.agencia.cnptia.embrapa.br/Repositorio/Manual+de+Metodos_000fzvhotqk02wx5ok0q43a0ram31wtr.pdf

[7] Corradi MM, Panosso AR, Martin Filho MV, La Scala Jr N. Crop residues on short-term CO₂ emissions in sugarcane production areas. Eng Agríc. 2013;33:699-708. doi:10.1590/S0100-69162013000400009

[8] Davidson EA, Swank WT. Environmental parameters regulating gaseous nitrogen losses from two forested ecosystems via nitrification and denitrification. Appl Environ Microbiol. 1986;52:1287-92. doi:10.1111/j.1750-3841.2007.00346.x

[9] Epron D, Nouvellon Y, Roupsard O, Mouvondy W, Mabiala A, SaintAndre L, Joffre R, Jourdan J, Bonnefond JM, Berbigier P, Hamel O. Spatial and temporal variations of soil respiration in a eucalyptus plantation in Congo. For Ecol Manage. 2004;202:149-60. doi:10.1016/j.foreco.2004.07.019

[10] Fang C, Moncrieff JB, Gholz HL, Clark KL. Soil CO₂ efflux and its spatial variation in a Florida slash pine plantation. Plant Soil. 1998;205:135-46. doi:10.1023/A:1004304309827

[11] Isaaks EH, Srivastava RM. An introduction to applied geostatistics. New York: Oxford University; 1989.

[12] Kemper WD, Chepil WS. Size distribution of aggregates. In: Black CA, editor. Methods of soil analysis: physical and mineralogical properties, including statistics of measurement and sampling, Madison: Soil Science Society of America; 1965. Pt 1. p.499-510.

[13] Kononova MM. Humus of virgin and cultivated soils. In: Gieseking JE, editor. Soil components. Berlin: Springer; 1975. p.475-526.

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	Dry period					Rainy period

	Mean	SD	Min	Max	CV	Mean	SD	Min	Max	CV
					%					%
	SG-5
FCO₂	1.19 bB	0.90	-0.56	4.59	75.94	2.33 aA	0.77	1.25	5.80	33.31
Sm	11.16 aB	1.85	9.00	17.00	16.62	38.41 aA	2.46	32.33	44.78	6.40
AFPS	44.40 aA	9.66	35.06	86.68	21.76	17.07 bB	9.17	5.86	54.88	53.73
	SG-10
FCO₂	2.62 aA	1.01	1.21	8.26	38.42	2.89 aA	1.42	0.93	8.06	49.42
Sm	10.17 bB	1.42	8.00	14.00	13.96	29.71 aA	2.58	24.00	35.00	8.69
AFPS	43.24 aA	4.81	33.30	57.47	11.20	26.07 aB	9.20	13.90	65.26	35.28
St	18.90 b	0.42	17.20	19.71	2.25	23.39 a	5.67	19.37	46.25	24.26

	SG-5					SG-10

	Mean	SD	Min	Max	CV	Mean	SD	Min	Max	CV
					%					%
OC (g kg^-1)	3.24 a	0.89	2.11	6.24	27.63	2.50 b	0.29	1.65	3.08	11.86
TP (g kg^-1)	54.45 a	6.76	46.45	85.57	12.41	53.38 a	4.16	46.45	66.89	7.79
Macro (g kg^-1)	18.42 b	4.76	3.58	36.87	25.87	23.48 a	4.96	11.29	43.84	21.15
Bd (Mg m^-3)	1.27 b	0.13	0.86	1.59	10.71	1.37 a	0.14	1.07	1.72	10.18
PR (MPa)	5.04 a	1.38	2.15	10.21	27.36	3.45 b	1.30	0.56	7.45	37.73
MWD (mm)	1.39 b	0.46	0.67	2.50	33.47	1.74 a	0.49	0.71	3.06	28.31
Clay (g kg^-1)	522 a	59.45	397	620	11.37	531 a	31.29	350	541	7.25
pH	4.82 a	0.11	4.60	5.20	2.34	4.82 a	0.25	4.20	5.60	5.34
P (mg dm^-3)	35.50 a	18.19	9.00	95.00	51.25	31.35 b	18.28	10.00	90.00	58.30
S (mg dm^-3)	7.84 a	4.42	2.00	19.60	65.35	7.26 a	0.26	0.15	1.40	55.49
Ca (cmol_c dm^-3)	4.17 a	0.94	2.50	7.30	22.63	3.07 b	0.73	1.60	5.00	23.82
Mg (cmol_c dm^-3)	1.28 a	0.22	0.90	1.80	17.30	0.92 b	0.24	0.50	1.90	26.16
Fe (mg dm^-3)	39.91 b	9.40	23.50	76.50	23.55	129.45 a	19.93	71.50	184.00	15.40

	SG-5		SG-10

	FCO₂ (DryP)	FCO₂ (RainP)	FCO₂ (DryP)	FCO₂ (RainP)
FCO₂ (µmol CO₂ m^-2 s^-1) (DryP)	-	-	-	-
FCO₂ (µmol CO₂ m^-2 s^-1) (RainP)	0.008	-	0.26	-
St (°C) (DryP)	0.001	-0.15	0.23	0.09
St (°C) (RainP)	-0.09	-0.14	0.26	0.1
Sm (%) (DryP)	-0.09	-0.16	-0.29	0.04
Sm (%) (RainP)	-0.09	0.05	-0.12	-0.17
AFPS (DryP)	-0.01	0.06	0.08	0.28
AFPS (RainP.)	-0.01	0.02	0.23	0.28
OC (g kg^-1)	-0.02	0.06	-0.06	0.14
TP (g kg^-1)	-0.03	0.02	0.04	0.28
Macro (g kg^-1)	0.02	-0.02	-0.07	-0.09
Bd (Mg m^-3)	0.0005	-0.02	0.01	0.03
PR (MPa)	-0.02	0.05	0.03	0.04
MWD (mm)	0.26	0.0008	0.01	-0.01
Clay (g kg^-1)	-0.001	-0.05	0.05	0.09
pH	0.09	-0.09	-0.04	0.12
P (mg dm^-3)	-0.09	-0.03	0.21	0.17
S (mg dm^-3)	0.30	-0.05	-0.03	-0.06
Ca (cmol_c dm^-3)	-0.03	0.02	-0.01	0.23
Mg (cmol_c dm^-3)	-0.06	0.12	0.05	0.25
Fe (mg dm^-3)	-0.09	-0.16	0.16	0.14

Brasil

Brasil

Spatial and Temporal Variability of Soil CO₂ Flux in Sugarcane Green Harvest Systems

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

Description of the experimental areas

Climatic data

Evaluation of soil CO2 flux

Evaluation of soil properties

Statistical analyses

RESULTS AND DISCUSSION

Temporal variability

Spatial variability

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History

Brasil

Brasil

Spatial and Temporal Variability of Soil CO2 Flux in Sugarcane Green Harvest Systems

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

Description of the experimental areas

Climatic data

Evaluation of soil CO2 flux

Evaluation of soil properties

Statistical analyses

RESULTS AND DISCUSSION

Temporal variability

Spatial variability

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History

Spatial and Temporal Variability of Soil CO₂ Flux in Sugarcane Green Harvest Systems