Abstract

CO₂ effluxes from streams and rivers have been hypothesized to be a critical pathway of carbon flow from the biosphere back to the atmosphere. This study was conducted in three small Amazonian catchments to evaluate carbon evasion and dynamics, where land-use change has occurred on small family-farms. Monthly field campaigns were conducted from June 2006 to May 2007 in the Cumaru (CM), Pachibá (PB) and São João (SJ) streams. Electrical conductivity, pH, temperature, and dissolved oxygen measurements were done in situ, while water samples were collected to determine dissolved organic carbon (DOC) and dissolved inorganic carbon (DIC) concentrations, as well as carbon dioxide partial pressures (pCO₂) and CO₂ evasion fluxes. Instantaneous discharge measured by a current meter was used to calculate DOC fluxes. Considering all the sites, DOC, DIC, pCO₂, and CO₂ flux measurements ranged as follows, respectively: 0.27 - 12.13 mg L^-1; 3.5 - 38.9 mg L^-1; 2,265 - 26,974 ppm; and 3.39 - 75.35 μmol m^-2 s^-1. DOC annual flux estimates for CM, SJ and PB were, respectively, 281, 245, and 169 kg C ha^-1. CO₂ evasion fluxes had an average of 22.70 ± 1.67 μmol m^-2 s^-1. These CO₂ evasion fluxes per unit area were similar to those measured for major Amazonian rivers, thus confirming our hypothesis that small streams can evade substantial quantities of CO₂. As secondary vegetation is abundant as a result of family farming management in the region, we conclude that this vegetation can be a major driver of an abundant carbon cycle.

Keywords:
Amazon basin; biogeochemistry; carbon dioxide evasion.

Resumo

Os fluxos de CO₂ a partir de igarapés e rios têm sido sugeridos como uma possível e crítica via para os fluxos de retorno do carbono da biosfera para a atmosfera. Esse estudo foi conduzido em três pequenas bacias amazônicas para avaliar a dinâmica e evasão de carbono em região onde as mudanças de uso da terra resultaram em paisagens dominadas por pequenas propriedades de agricultores familiares. Campanhas de campo mensais foram realizadas no período de Junho/2006 a Maio/2007 nas bacias dos igarapés Cumaru (CM), Pachibá (PB) e São João (SJ). Medidas de condutividade elétrica, pH, temperatura e oxigênio dissolvido foram realizadas in situ, enquanto coletas de amostras de água fluvial foram feitas para determinação das concentrações de carbono orgânico dissolvido (COD) e de carbono inorgânico dissolvido (CID), assim como para as medidas da pressão parcial do dióxido de carbono (pCO₂) e dos fluxos de evasão de CO₂. A vazão instantânea medida em cada campanha foi usada para cálculo dos fluxos de COD. Considerados todos os igarapés, os fluxos de COD, CID, pCO₂, e CO₂ variaram da seguinte forma, respectivamente: 0,27 - 12,13 mg L^-1; 3,5 - 38,9 mg L^-1; 2.265 - 26.974 ppm; and 3,39 - 75,35 μmol m^-2 s^-1. Os fluxos anuais estimados de COD em CM, SJ e PB foram respectivamente 281, 245 e 169 kg C ha^-1. Os fluxos de evasão de CO₂ variaram de 3,39 a 75,35 μmol m^-2 s^-1, com média de 22,70 ± 1,67 μmol m^-2 s^-1. Essa evasão de CO₂ por unidade de área foi similar aos maiores fluxos de evasão medidos nos principais rios amazônicos, confirmando assim nossa hipótese de que nos pequenos igarapés podem ocorrer valores substanciais de evasão de CO₂. Como a floresta secundária é abundante nessa região, em decorrência da prática da agricultura familiar, concluímos que essa vegetação pode ser o fator determinante da ciclagem abundante de carbono.

Palavras-chave:
Bacia Amazônica; biogeoquímica; evasão de dióxido de carbono.

1. INTRODUCTION

Riverine CO₂ concentrations in Amazonian lowlands are 5-30 times supersaturated with respect to atmospheric equilibrium; such conditions may be prevalent throughout Amazonian streams and rivers (Richey et al., 2002RICHEY, J. E.; MELACK, J. M.; AUFDENKAMPE, A. K.; BALLESTER, V. M.; HESS, L. L. Outgassing from Amazonian rivers and wetlands as a large tropical source of atmospheric CO2. Nature,v. 416, p. 617-620, 2002. https://doi.org/10.1038/416617a
https://doi.org/10.1038/416617a... ). It was estimated by Richey et al. (1990RICHEY, J. E.; HEDGES, J. I.; DEVOL, A. H.; QUAY, P. D.; VICTORIA, R. L.; MARTINELLI, L. et al. Biogeochemistry of carbon in the Amazon River. Limnology and Oceanography, v. 35, p. 352-371, 1990. https://doi.org/10.4319/lo.1990.35.2.0352
https://doi.org/10.4319/lo.1990.35.2.035... ) that CO₂ outgassed from the Amazon River is more than ten times the amount of carbon exported to the ocean in the form of total organic carbon or DIC, and that this CO₂ evasion from rivers and wetlands of the central Amazon basin constitutes an important carbon loss pathway. Mayorga et al. (2005)MAYORGA, E.; AUFDENKAMPE, A. K.; MASIELLO, C. A.; KRUSCHE, A. V.; HEDGES, J. I.; QUAY, P. D. et al. Young organic matter as a source of carbon dioxide outgassing from Amazonian rivers. Nature, v. 436, p. 538-541, 2005. https://doi.org/10.1038/nature03880
https://doi.org/10.1038/nature03880... suggested that a small, rapidly cycling pool of organic carbon is responsible for the large carbon fluxes from land to water to atmosphere in the humid tropics. In contrast, Davidson et al. (2010)DAVIDSON, E. A.; FIGUEIREDO, R. O.; MARKEWITZ, D.; AUFDENKAMPE, A. K. Dissolved CO2 in small catchment streams of eastern Amazonia: A minor pathway of terrestrial carbon loss. Journal of Geophysical Research, v. 115, 2010. https://doi.org/10.1029/2009JG001202
https://doi.org/10.1029/2009JG001202... estimated that CO₂ efflux from a 10 km² watershed in the eastern Amazon was small relative to terrestrial fluxes.

Several studies in the Amazon Basin have demonstrated a strong connection between terrestrial processes and the chemistry of lower-order streams (McClain and Richey, 1996MCCLAIN, M. E.; RICHEY, J. E. Regional-scale linkages of terrestrial and lotic ecosystems in the Amazon basin: a conceptual model for organic matter. Archiv Fur Hydrobiologie, v. 113, p. 111-125, 1996. https://dx.doi.org/10.1127/lr/10/1996/111
https://dx.doi.org/10.1127/lr/10/1996/11... ; Elsenbeer and Lack, 1996ELSENBEER, H.; LACK, A. Hydrometric and hydrochemical evidence for fast flowpaths at La Cuenca, Western Amazonia. Journal of Hydrology, v. 1, n. 80, p. 237-250, 1996. https://doi.org/10.1016/0022-1694(95)02889-7
https://doi.org/10.1016/0022-1694(95)028... ). Stream channels are linked to the land by groundwater flows, surface and subsurface runoff, infiltration from riparian zones, and by direct inputs of throughfall and terrestrial detritus affecting C dynamics at the terrestrial-aquatic interface as observed by Johnson et al. (2006a)JOHNSON, M. S.; LEHMANN, J.; COUTO, E. G.; NOVAS-FILHO, J. P.; RIHA, S. DOC and DIC in flowpaths at Amazonian headwater catchments with hydrologically contrasting soils. Biogeochemistry, v. 81, p. 45-57, 2006a. https://doi.org/10.1007/s10533-006-9029-3
https://doi.org/10.1007/s10533-006-9029-... in two Amazonian headwater catchments. The rates of these processes determine the main C sources and the magnitudes of land-water C transfers in small watersheds (Neill et al., 2006NEILL, C.; ELSENBEER, H.; KRUSCHE, A. V.; LEHMANN, J.; MARKEWITZ, D.; FIGUEIREDO, R. O. Hydrological and biogeochemical processes in a changing Amazon: results from small watershed studies and the large-scale biosphere-atmosphere experiment. Hydrological Processes, v. 20, p. 2467-2476, 2006. https://doi.org/10.1002/hyp.6210
https://doi.org/10.1002/hyp.6210... ). More recently, Zanchi et al. (2015)ZANCHI, F. B.; WATERLOO, M. J.; TAPIA, A. P.; ALVARADO BARRIENTOS, M. S.; BOLSON, M. A.; LUIZÃO, F. J. et al. Water balance, nutrient and carbon export from a heath forest catchment in central Amazonia, Brazil. Hydrological Processes,v. 29, p. 36333648, 2015. https://doi.org/10.1002/hyp.10458
https://doi.org/10.1002/hyp.10458... pointed out that further studies are needed to understand the processes that lead to dissolved organic carbon (DOC) formation in soils, especially in the poorly drained valley soils of Amazonian rainforest catchments, and that it would be important to include the dissolved inorganic C measurement to calculate the total carbon export from such areas.

Because the primary production of undisturbed Amazon streams is small (McClain and Elsenbeer, 2001MCCLAIN, M. E.; ELSENBEER H. Terrestrial inputs to Amazon streams and internal biogeochemical processing. In: MCCLAIN, M. E. et al. (Ed.). Biogeochemistry of the Amazon Basin. New York: Oxford University Press, 2001.), inputs from terrestrial sources grow in importance for small stream fluxes of nutrients and carbon. For downstream reaches, riparian ecosystems also continue to influence small catchment biogeochemistry. For instance, the fact that the phreatic level is at or very close to the soil surface in riparian forest, as stated by Zanchi et al. (2011)ZANCHI, F. B.; WATERLOO, M. J.; DOLMAN, A. J.; GROENENDIJK, M.; KESSELMEIER, J.; KRUIJT, B. et al . Influence of drainage status on soil and water chemistry, litter decomposition and soil respiration in central Amazonian forests on sandy soils. Revista Ambiente & Água, v. 6, n. 1, p. 6-29, 2011. http://dx.doi.org/10. 4136/ambi-agua.170
http://dx.doi.org/10. 4136/ambi-agua.170... , degassing of groundwater with high pCO₂ might also contribute to soil respiration before such groundwater reaches the stream channel.

Richey et al. (1997)RICHEY, J. E.; WILHELM, S. R.; MCCLAIN, M. E.; VICTORIA, R. L.; MELACK, J. M.; LIMA, C. A. Organic matter and nutrient dynamics in river corridors of the Amazon Basin and their response to anthropogenic change. Ciência e Cultura, v. 49, p. 98-110, 1997. suggested that land use changes in tropical regions will be first reflected in the biogeochemistry of small streams. However, the effects of land use change on small Amazonian catchments may vary locally and regionally, depending upon variations in soil properties as well as the agriculture management history (Davidson et al., 2004DAVIDSON, E. A.; NEILL, C.; KRUSCHE, A. V.; BALLESTER, M. V. R.; MARKEWITZ, D.; FIGUEIREDO, R. O. Loss of Nutrients from Terrestrial Ecosystems to Streams and the Atmosphere following Land Use Change in Amazonia. In: DEFRIES, R., ASNER, G.; HOUGHTON, R. (Eds.). Ecosystems and Land Use Change. Washington, DC: American Geophysical Union, 2004. p. 147-158. (Geophysical Monograph Series, 153)). Consequently, in the Eastern Amazon of Brazil, effects on biogeochemical cycles and hydrology are expected due to shifting cultivation with slash-and-burn land preparation. In these areas, burning secondary forests - the so called “capoeiras” - is an essential activity of traditional agricultural systems and has been carried out in this region for more than a hundred years (Sommer et al., 2004SOMMER, R.; VLEK, P. L. G.; SÁ, T. D. A.; VIELHAUER, K.; COELHO, R. F. R.; FÖLSTER, H. Nutrient balance of shifting cultivation by burning or mulching in the Eastern Amazon - evidence for subsoil nutrient accumulation. Nutrient Cycling in Agroecosystems, v. 68, p. 257-271, 2004. https://doi.org/10.1023/B:FRES.00000 19470.93637.54
https://doi.org/10.1023/B:FRES.00000 194... ).

The main objective of this research was to evaluate the evasion of CO₂ from small streams in the Eastern Amazon in catchments mainly comprised of small family farms. We quantified dissolved organic and inorganic carbon (DOC and DIC), pCO₂, CO₂ evasion fluxes, and other biogeochemical attributes in three small streams. We hypothesized that CO₂ evasion fluxes would be greater at headwater sampling stations where the percentage of forest cover of the upstream basin is larger and results in higher CO₂ inputs from root and microbial respiration. Consequently, we propose that secondary vegetation, in these disturbed and managed small Amazonian catchments, still has an important role as a driver of carbon dynamics.

2. MATERIALS AND METHODS

2.1. Study area characteristics

This research was conducted in three small watersheds located in the municipalities of Marapanim and Igarapé-Açu in the Brazilian state of Pará. Mean annual temperature is 26°C with little seasonal variation. The average annual rainfall amounts to about 2500 mm ±10%, of which 60% typically falls during the wet season between January and April (Bastos and Pacheco, 1999BASTOS, T. X.; PACHECO, N. A. Características agroclimatológicas de Igarapé-Açu, PA, e suas implicações para as culturas anuais: feijão, caupi, milho, arroz e mandioca. Embrapa Amazônia Oriental. Boletim de Pesquisa, v. 25, p. 30, 1999.).

The landscape has a flat to slightly undulating relief at an elevation of 30 to 70 m a.s.l. The soils in the studied catchments are classified as Typic Hapludults and are acidic and surficially sandy (65-80% sand). They are characterized by low C and N contents, as well as by low plant-available P, a low cation exchange capacity (CEC), and high subsoil aluminum saturation. The texture is loamy sand in the topsoil and sandy clay loam in the deeper layers (Sommer et al., 2004SOMMER, R.; VLEK, P. L. G.; SÁ, T. D. A.; VIELHAUER, K.; COELHO, R. F. R.; FÖLSTER, H. Nutrient balance of shifting cultivation by burning or mulching in the Eastern Amazon - evidence for subsoil nutrient accumulation. Nutrient Cycling in Agroecosystems, v. 68, p. 257-271, 2004. https://doi.org/10.1023/B:FRES.00000 19470.93637.54
https://doi.org/10.1023/B:FRES.00000 194... ).

After significant deforestation began in the eastern Amazon about 140 years ago, agriculture in these areas has been based on slash-and-burn shifting cultivation. As a result, the dominant vegetation that was once moist lowland tropical forest is now a mosaic of mostly secondary forests, pastures, and small agricultural fields of corn, rice, beans, peppers, passion fruit and manioc (Vieira et al., 2003VIEIRA, I. C. G.; ALMEIDA, A. S.; DAVIDSON, E. A.; STONE, T. A.; CARVALHO, C. J. R.; GUERRERO, J. B. Classifying successional forests using Landsat spectral properties and ecological characteristics in eastern Amazonia. Remote Sensing of Environment, v. 87, p. 470-481, 2003. https://doi.org/10.1016/j.rse.2002.09.002
https://doi.org/10.1016/j.rse.2002.09.00... ; Sommer et al., 2004SOMMER, R.; VLEK, P. L. G.; SÁ, T. D. A.; VIELHAUER, K.; COELHO, R. F. R.; FÖLSTER, H. Nutrient balance of shifting cultivation by burning or mulching in the Eastern Amazon - evidence for subsoil nutrient accumulation. Nutrient Cycling in Agroecosystems, v. 68, p. 257-271, 2004. https://doi.org/10.1023/B:FRES.00000 19470.93637.54
https://doi.org/10.1023/B:FRES.00000 194... , Watrin et al., 2009WATRIN, O. S.; GERHARD, P.; MACIEL, M. N. M. Dinâmica do uso da terra e configuração da paisagem em antigas áreas de colonização de base econômica familiar, no nordeste do estado do Pará. Geografia, v. 34, n. 3, p. 455-472, 2009.) that are dissected by streams fringed with a strip of riparian wetland forest (Wickel, 2004WICKEL, B. Water and nutrient dynamics of a humid tropical agricultural watershed in Eastern Amazonia. Göttingen: Cuvillier Verlag, 2004. 135p. ). Fertilizer inputs throughout the region are still limited.

The three low-order Amazonian streams studied in the present watershed evaluation are: the Cumaru and the São João Streams, in the Maracanã River Basin; and the Pachibá Stream, in the Marapanim River Basin (Figure 1). The watershed areas range from 320 to 1,850 ha, and channel widths vary from one to three meters. As is typical in the eastern Amazon, the studied streams possess small reservoirs along their course as a result of little dams formed by the dirt roads. Because of these dams the water-atmosphere equilibrium at sampling points behind the dams may be altered and thus these study stream may not describe the carbon dynamics in small free-flowing Amazonian streams in general. These dams, however, are typical of Amazonian streams in large agricultural landscapes occupied by small family farms.

2.2. Land cover/ land use classification

Geo-referencing and data analysis of the three study catchments were done at the Remote Sensing Laboratory of Embrapa Amazônia Oriental, in Belém (Pará state, Brazil), using Spring 4.2 (Câmara et al., 1996CÂMARA, G.; SOUZA, R. C. M.; FREITAS, U. M.; GARRIDO, J. SPRING: Integrating remote sensing and GIS by object-oriented data modelling. Computers & Graphics, v. 20, n. 3, p. 395-403, 1996. https://doi.org/10.1016/0097-8493(96)00008-8
https://doi.org/10.1016/0097-8493(96)000... ) and Envi 4.0 (ENVI, 2006ENVIRONMENT FOR VISUALIZING IMAGES - ENVI. Guia do ENVI. Available in: http://www.envi.com.br. Access in: March 2005.
http://www.envi.com.br.... ) software. To obtain information about land cover and land use, Landsat digital images were collected on June 9th, 2004 using Thematic Mapper (TM) bands 3, 4 and 5. Landsat imagery in MrSID format was obtained from Instituto Brasileiro de Geografia e Estatística (IBGE) and used as a cartographic base at a 1:100.000 scale.

After geo-referencing and registration of the images, a radiometric normalization process was used to unify the land cover and land use aspects in the selected images. For the image classification, a regionalized supervised classification was used with a Bhattacharya algorithm and ground truthing (Watrin et al., 2005WATRIN, O. S.; CRUZ, C. B. M.; SHIMABUKURO, Y. E. Análise evolutiva da cobertura vegetal e do uso da terra em projetos de assentamentos na fronteira agrícola amazônica, utilizando geotecnologias. Geografia,v. 30, n. 1, p. 59-76, 2005.). Land cover and land use class were quantified for each of the three studied watersheds using thematic images from both study years (2006-2007). Finally, three maps were generated for each catchment, presenting six land use classes: crop fields, pasture, dirty pasture (pasture with some woody encroachment), younger secondary vegetation (young capoeira), older secondary vegetation (old capoeira), and forest.

2.3. Sampling and analytical methods

Daily rainfall data were recorded with a weather station (Campbell CR23X. Logan, UT) located in the Cumaru catchment (geographical coordinates: 01º12’S and 47º36’W).

Four stream water sampling stations were established in the Cumaru (CM-1, CM-2, CM-3 and CM-4), and two stations were established in each of the other streams - São João (SJ-1 and SJ-2) and Pachibá (PB-1 and PB-2).

Sampling stations were characterized as “headwater” stations, where water is just emerging from soils into stream channels or “downstream” stations, which were located in the main channel of the catchments (Table 1). In the PB stream the PB-1 station is furthest from the groundwater emergence. Physicochemical parameter measurements as well as stream water sampling for DOC concentration analysis were done on a nearly monthly basis from June 2006 to May 2007 at all stations. Twelve discharge measurements were collected at the same time, but only in the most-downstream station of each catchment (CM-4, SJ-2 and PB-2). Stream discharge was estimated by measuring cross sectional area and flow with a current meter (Global Water, model FP201, Gold River, CA) following the methods of Rantz (1982)RANTZ, S. E. Measurement and computation of stream flow: Volume 1, Measurement of 681 stage height and discharge, USGS. Washington, DC: US Government Printing 682 Office, 1982. (Water-supply paper, 2175). Electric conductivity, pH, dissolved oxygen, and water temperature were measured in situ by, respectively, a conductivity meter (VWR, Model 2052, Batavia, IL), a pH meter (ORION, Model 290A plus, Waltham, MA), and an oxygen meter (YSI, Yellow Springs, OH).

For DOC determination, we collected three 60 ml sample replicates that were filtered through pre-combusted glass fiber filters, stored in 20 ml glass vials, and preserved with phosphoric acid (H₃PO₄) in the field. Samples were placed in cold storage (~4ºC) until they arrived at an EMBRAPA laboratory in the city of Belém, 150 km from Igarapé-Açu, for analysis of DOC by combustion (Shimadzu TOC V CSN, Columbia, MD).

Annual output fluxes of DOC were estimated for each studied catchment over the period June 2006 - May 2007 and normalized per catchment area to allow comparison to each other and to other stream and riverine DOC flux estimates in the Amazon. However, as we did not specifically quantify stormflow events, calculated DOC fluxes likely underestimate the annual flux.

Sampling for the partial pressure of CO₂ (pCO₂) was done over seven months (June to December 2006). Measurements for pCO₂ were done by headspace extraction, which equilibrates a 60 ml water sample bottle with a 60 ml air sample bottle connected through a valve system. Air samples are removed by syringe and injected for storage into a triplicate set of silicon-sealed 30 ml glass penicillin vials. Analysis of pCO₂ by gas chromatography (Shimadzu GC17A, Columbia, MD) was performed at the CENA laboratory in Piracicaba, São Paulo. As CO₂ evasive fluxes depend on the atmospheric CO₂ concentrations, atmospheric samples were also collected in triplicate 60 ml syringes which were analyzed in the same laboratory. Air temperature and wind speed were measured by a field digital anemometer (Kestrel 3000 Wind Meter, Sylvan Lake, MI) at each sampling station.

DIC concentrations were estimated by the speciation of measured pCO₂ values using thermodynamic equilibrium equations (Skirrow, 1975, according to Rasera, 2005RASERA, M. F. F. L. O papel das emissões de CO2 para a atmosfera, em rios da bacia do Ji-Paraná (RO), no ciclo regional do carbono. 2005. 69f. Dissertação (Mestrado) - Centro de Energia Nuclear na Agricultura, Piracicaba, 2005.).

CO₂ evasive fluxes were measured, as detailed by Rasera et al. (2008)RASERA, M. F. F. L; BALLESTER, V. M.; KRUSCHE, A. V.; SALIMON, C.; MONTEBELO, L. A.; ALIN, S. R. et al. Estimating the Surface Area of Small Rivers in the Southwestern Amazon and Their Role in CO2 Outgassing. Earth Interactions, v. 12, n. 6, p. 1-16, 2008. https://doi.org/10.1175/2008EI257.1
https://doi.org/10.1175/2008EI257.1... , using a floating chamber (with a volume of 18.3 L and a water surface of 0.1 m²) and a CO₂ gas analyzer (LI-COR, Model LI-820, Lincoln, NE) connected to a notebook for data storage. In total, three collections using the floating chamber were conducted at each station, once in February, March and April 2007.

However, monthly CO₂ evasive fluxes for the period from June to December 2006 were calculated using pCO₂ values. These fluxes were calculated according Rasera (2005)RASERA, M. F. F. L. O papel das emissões de CO2 para a atmosfera, em rios da bacia do Ji-Paraná (RO), no ciclo regional do carbono. 2005. 69f. Dissertação (Mestrado) - Centro de Energia Nuclear na Agricultura, Piracicaba, 2005. using Equation 1.

where:

F_CO2 is the flux (mol CO₂ m^-2 s^-1);

(ΔpCO₂/Δt) is the pCO₂ variation through time given by the slope (ppm s^-1) of the linear regression between time and pCO₂ in the chamber;

V is the total volume of the system (chamber, tubes, and analyzer cell);

R is the universal gas constant (0.08206 atm l mol^-1 K^-1);

T is the air temperature (K);

A is the surface area of the chamber (m²).

Finally, parametric statistics of hydrogeochemical data were analyzed after confirmation of the normal distribution of each variable using the Shapiro-Wilk normality test. If necessary, data were transformed to approximate normality. To evaluate land use impacts or sampling locations, a number of repeated-measure, mixed-effects models were tested with the following form (Equation 2):

where:

Y_ijk is the stream component of interest (i.e., concentration or evasion) for month i, stream j, and station k within stream j.

In this model, β _o is the intercept;

_^β1 is the coefficient of the covariate percent land cover (%cov);

_^mi is the fixed effect of month I;

_^li is the fixed effects for location (headwater or downstream);

_^bj and _^bk(j) are random effects of stream j and station k within stream j with distribution N (0, σ² _m ) and N (0, σ² _st ), respectively, and

_^eijk is the error term with distribution N (0, σ²).

The N signifies it is a normal distribution. The 0 indicates the mean of the normal distribution is zero. The sigma squared (σ²) is the variance of that normal distribution around zero. The land cover values utilized for each station were estimated in the area upstream of collection. The repeated measure subject is a station within a stream, and error terms associated with the same station at different time points are assumed to have a covariance structure. A number of repeated measures covariance structures were evaluated, but a first-order autoregressive model usually produced the best results and were used throughout. Model fits were tested with -2 times the residual log likelihood, Akaike’s information criteria (AIC), AICC (finite population corrected AIC), and Bayesian information criteria (BIC).

3. RESULTS AND DISCUSSION

3.1. Land use patterns

Spatial distribution of the land use classes can be seen in Figure 2, along with the percent (%) of the total catchment area for each land use class in Table 2. The predominance of small family farming resulted in a landscape where secondary vegetation of different ages (young and old capoeiras) comprised the largest area in all catchments.

Young and old capoeiras, which can be classified as fallow vegetation, together with crop fields (manioc, bean, rice, corn, pepper and passionfruit) comprised the predominant land cover classes in the studied catchments; these three land use classes, if summed together, are slightly greater in Cumaru catchment (75.3%) than in São João (68.2%) and Pachibá (61.6%) catchments.

Pasture (both managed and unmanaged {locally called dirty pasture}) was also predominant in catchments with less fallow or cropland: Pachibá catchment had 46.1% of its area under both pasture types combined followed by São João with 24.4% and Cumaru with 18.9%.

Moreover, mature forest was not abundant in the study catchments, with only 5% forest cover in Cumaru and São João catchments, and almost none in the Pachibá catchment (0.1%). These proportions reflect faster deforestation processes occurring in larger rural properties than in small farm areas.

Although headwater sampling stations in the Cumaru catchment (CM-1 and CM-2) were immediately surrounded by old capoeiras, they were situated in drainage areas mainly covered with young capoeiras and small crop fields. In this sector of the Cumaru catchment, there is neither pasture nor forest. However, the main channel sampling stations in the Cumaru catchment were located in areas of old capoeiras and forest (CM-3 and CM-4), but these drainage areas were mainly occupied by young capoeiras with some pastures in the uplands.

In São João catchment, the headwater sector (upstream area from SJ-1 station) also consisted of drainage areas covered by young capoeiras and small crop fields, with only a small and undetectable (by satellite, due to the 30m x 30m resolution of Landsat imagery) remnant of primary vegetation observed there. Conversely, in the downstream sector of the São João catchment (upstream from SJ-2 station), areas were mainly occupied by young capoeiras, though there were some pasture areas separated from the stream by old capoeiras, as well as a remnant forest.

In the Pachibá catchment, the upper sampling station (PB-1) was surrounded by a young capoeira, though the riparian zone upstream of this area contained old capoeiras and pasture. Overall, most of the drainage area of the Pachibá catchment consisted of pasture, followed by old capoeiras. This difference, in terms of land use comparing Pachibá with the other two studied catchments, is also evident downstream of the upper sampling station. The PB-2 sampling station was located in a reach of the stream where a road functioned as a dam, forming a little lake in which the riparian zone was occupied by a crop field and a dirty pasture next to an old capoeira.

3.2. Hydrologic properties

Rainfall totaled 2,143 mm for the study period, which was 14% less than the annual rainfall average for this area. The largest total monthly rainfall occurred in February and April (416.8 and 417.2 mm, respectively), while the smallest total monthly rainfall occurred in October and December (23.8 and 12.2 mm, respectively) (Figure 3).

In June, at the start of the study, the wet season was nearing its end, though there were still frequent rain events. However, by the second half of August, the dry season was well established, remaining so until the middle of January when the wet season returned slowly. From February to May almost-daily rain events were very intense.

Discharge in Cumaru and São João Streams decreased during the first half of the one-year study as a response to less rainwater inputs. However, this response was not detected in Pachibá Stream, as its flows were regulated by a dam that was elevated in November due to road maintenance work. The dam filled thereafter maintaining low constant flows for the first half of the year. Not surprisingly, stream discharge increased with the return of the wet season (Figure 3). Overall, differences in stream discharge reflected the different sizes of each catchment area, as larger catchments resulted in larger stream flows.

3.3. Hydro-biogeochemical properties

The ranges of electrical conductivity (EC), pH, temperature (Temp), and dissolved oxygen (DO) values measured in the three streams were respectively: 15.9 - 31.0μS cm^-1; 3.30 - 5.24; 24.9 - 29.6ºC; and 0.3 - 6.9 mg L^-1. Stream water in the headwater stations tended to have low pH and DO, but high electrical conductivity compared to the downstream sampling stations (Table 3).

The ranges of DOC, DIC, pCO₂, and CO₂ flux values measured in the three streams were respectively: 0.27 - 12.13 mg L^-1; 3.5 - 38.9 mg L^-1; 2,260 - 26,900 ppm; and 3.39 - 75.3 μmol m^-2 s^-1. Moreover, DOC annual flux estimates for CM, SJ and PB were respectively 281, 245, and 169 kg ha^-1 (Table 4).

DOC concentrations tended to increase downstream in all streams (Figure 4) and sampling location (headwater or downstream) had a significant effect on concentration (Figure 4). On the other hand, DIC and pCO₂ decreased downstream in CM and SJ, but not in PB (Figure 4), although across all streams location still had a significant effect on LogDIC (Table 5). CO₂ evasion fluxes decreased downstream in SJ and PB, but not among CM stations, although once again across all streams locations was a significant effect (Figure 4).

Time series data for DOC, DIC, and CO₂ evasion for each station of the three studied streams during the one-year study period indicated a significant effect of month on concentrations and fluxes (Figure 5). A clear pattern of higher DOC concentrations in the wet season was evident, but no similar seasonal patterns were evident for DIC and CO₂ evasion (Figure 5). CO₂ evasion fluxes were highest at two headwater stations (CM-2 and SJ-1) during the wet season (Figure 6). No other seasonal patterns were observed, however, for the other six stations. For all sample collections, CO₂ evasion rates were much higher at the São João headwater station (SJ-1), followed by the Pachibá headwater station (PB-1). In the São João and Pachibá catchments, the downstream stations have the smallest CO₂ evasion fluxes. The four Cumaru stations were intermediate to these levels.

3.4. Discussion

Low EC and pH values at the three studied streams reflected the acidity and low fertility of the soils of the catchments. We did not detect any signal of agricultural nutrient inputs based on EC measurements; instead, higher EC values are likely due to high concentrations of H⁺ indicated by low pH. Although fertilizer use is limited in these catchments, burning fallow vegetation is a management practice widely used throughout the catchments that increases soil nutrients. Remnant riparian forest, that have been mentioned in the studied area description, may have been filtering elements such as calcium (Ca²⁺) and potassium (K⁺) that would normally enter stream water by overland flow, as reported by Figueiredo (2009)FIGUEIREDO, R. O. Processos hidrológicos e biogeoquímicos em bacias hidrográficas sob usos agrícola e agroflorestal na Amazônia Brasileira. In: PORRO, R. (Ed.). Alternativa Agroflorestal na Amazônia em Transformação. Brasília: Embrapa Informação Tecnológica, 2009. p. 477-500. for the Cumaru catchment.

At the headwater sampling stations, lower pH values could be a response to both (1) leaching of dissolved organic acids or (2) high dissolved CO₂ concentrations resulting from soil organic matter mineralization and root respiration of the old capoeiras in the riparian zones. Higher EC values at headwater sampling stations (CM-1, CM-2 and SJ-1) might also result from higher organic matter mineralization rates leading to high H⁺ concentrations or direct inputs of CO₂. EC correlation to DIC (Pearson correlation coefficient r = 0.815) suggests that CO₂ inputs rather than dissolved organic matter leaching is the driver of pH variation along the streams. That is not the same pattern found at blackwater catchments, where strong and positive relationships between EC and DOC concentration were found in stream water (Monteiro et al., 2014MONTEIRO, M. T. F. ; OLIVEIRA, S. M. ; LUIZÃO, F. J. ; CÂNDIDO, L. A. ; ISHIDA, F. Y. ; TOMASELLA, J. Dissolved organic carbon concentration and its relationship to electrical conductivity in the waters of a stream in a forested Amazonian blackwater catchment. Plant Ecology & Diversity, v. 7, p. 205213, 2014. http://dx.doi.org/10.1080/17550874.2013.820223
http://dx.doi.org/10.1080/17550874.2013.... ). Since these three studied catchments in the Eastern Amazon have high mineralization rates as described, this means that DOC is rapidly transformed to DIC.

Dissolved oxygen depletion in the headwaters of CM and SJ might also result from organic matter mineralization in the streams, although DOC is poorly correlated with DO (r < 0.05). In contrast, DO and DIC are strongly correlated in streams CM (r = -0.95) and SJ (r = -0.7). This result suggests that the low DO at these headwater stations may reflect groundwater inputs of CO₂ saturated water and limited initial CO₂ evasion. The headwaters possess small stream water surface area and low current speed with a lack of visible turbulence. As waters move downstream, CO₂ is evaded and DO replenished through turbulent mixing.

The opposite spatial pattern for DO (higher upstream and lower downstream) at the Pachibá catchment might be explained by instream processes occurring in the pond that was created by a dam located at the PB-2 sampling station. Decomposition of macrophyte and phytoplankton communities in the pond could deplete DO. It is also possible that the PB stations are simply too close together with PB-1 too far downstream such that turbulent mixing has already occurred and neither station actually represents the headwater situation (Rosa, 2007ROSA, M. B. S. Dinâmica do Carbono em Pequenas Bacias de Drenagem Sob Uso de Agricultura Familiar na Amazônia Oriental. 2007. Dissertação (Mestrado) - Universidade Federal do Pará, Belém, 2007.).

Although DOC concentrations in the studied streams were similar to those of rivers in the tropics, as reported by Martins and Probst (1991)MARTINS, O.; PROBST, J. L. Biogeochemistry of Major African Rivers: Carbon and Mineral Transport. In: DEGENS, E. T.; KEMPE, S.; RICHEY, J. E. (Eds.). Biogeochemistry of Major World Rivers. Chichester: John Wiley & Sons, 1991. p. 127-155., DOC annual fluxes normalized per area at CM and SJ were higher than other Amazonian rivers and streams (Table 4). Increasing downstream DOC concentrations in CM and PB streams seemed to indicate that organic sources in the headwater areas of these catchments were not as abundant as in the headwater areas of SJ, where the terrestrial ecosystem is not as pristine. The large DOC yields per hectare found in the three studied streams do not result from cattle in the pastures or human populations, as densities of both are very small in the study catchments. As such, the capoeiras soils appear to be the most important source of organic matter for these aquatic systems (Table 2 and Figure 2).

Moreover, the pattern of higher DOC concentrations observed in the wet season, especially from March to May (Figure 5), is a seasonal pattern found by biogeochemical studies of other Amazonian rivers McClain, 1997MCCLAIN, M. E. Dissolved organic matter and terrestrial-lotic linkages in the central Amazon basin of Brazil. Global Biogeochemical Cycles, v. 11, n. 3, p. 295-311, 1997.; Richey et al., 1991RICHEY, J. E.; VICTORIA, R. L.; FORSBERG, B. R. The Biogeochemistry of a Major River System: The Amazon Case Study. In: DEGENS, E. T.; KEMPE, S.; RICHEY, J. E. (Eds.). Biogeochemistry of Major World Rivers Chichester: John Wiley & Sons,1991. p. 58-74.; Waterloo, 2006WATERLOO, M. J.; OLIVEIRA, M. O.; DRUCKER, D. P.; NOBRE, A. D.; CUARTAS, L. A.; HODNETT, M. G. et al. Export of organic carbon in run-off from an Amazonian rainforest blackwater catchment. Hydrological Processes, v. 20, n. 12, p. 2581-2597, 2006. https://doi.org/10.1002/hyp.6217
https://doi.org/10.1002/hyp.6217... ). Such temporal variation has been attributed to organic carbon in surface or interflow run-off from Amazonian rainforest catchments.

In contrast to DOC, variation in spatial patterns of DIC concentrations and pCO₂ revealed larger inorganic dissolved carbon in the headwater stations compared to downstream stations. Together with the low pH of stream water, this variation in DIC strongly indicated that the acidic groundwater that entered the streams in the headwater areas was enriched in aqueous CO₂, in contrast to downstream portions of the catchments where aqueous CO₂ was either evaded or converted to HCO₃ ^-. Conversion occurs through the well-known carbonate system processes whereby DIC is distributed among three species: H₂CO₃ ^* (aqueous CO₂ + carbonic acid), HCO₃ ^-, and CO₃ ^2- (Drever, 1982DREVER, J. I. The Geochemistry of Natural Waters. Englewoods Cliffs: Prentice-Hall, 1982.). As there is no important carbonate rock pool in these catchments, the DIC source results from either the mineralization of the terrestrial organic matter (likely in the soil rather than in the water column) or directly from root respiration. This CO₂ is subsequently dissolved in soil or ground waters, forming H₂CO₃ ^* and leached to stream water.

In addition to soil and groundwater sources, Marotta (2006)MAROTTA, H. Os fatores reguladores do metabolismo aquático e sua influência sobre o fluxo de dióxido de carbono entre os lagos e a atmosfera. Oecologia Brasiliensis, v. 10, n. 2, p. 177-185, 2006. points out that CO₂ fluxes can reveal a heterotrophic aquatic environment where the respiration rate is larger than the photosynthesis rate, which promotes CO₂ supersaturation in the water column and CO₂ evasion to the atmosphere. However, as previously indicated, these are low-productivity streams, so these types of instream processes are not expected to influence CO₂ fluxes.

Because of the expected larger DIC loads in the headwaters, we hypothesized that we would find larger CO₂ evasion fluxes at headwater sampling stations where forest cover also tends to be greater. Across all the streams, the locations of the station (headwater or downstream) was the best predictor of CO₂ evasion, while no land-use cover (forest, pasture, crop, young or old capoeira) was a significant predictor when all attributes were utilized (Table 5). When location was excluded, the best land-cover predictor was percent forest cover (Table 5), which derives partly from the fact that there is more forest in the headwaters of the catchments (Figure 2). Greater CO₂ efflux downstream was most evident in the SJ and PB catchments.

Annual estimated CO₂ evasion fluxes from the three streams of our study (Cumaru, São João, and Pachibá) ranged from 3.39 to 75.35 μmol m^-2 s^-1, with an average of 22.70 ± 1.67. Although Salimon (2005)SALIMON, C. I. Fluxos de carbono em ambientes fluviais e suas origens na Amazônia Ocidental. 2005. Relatório Científico (Pós-Doutorado) - Universidade de São Paulo, Piracicaba, 2005. reported a wide variability among CO₂ evasion fluxes in the Amazonian streams and rivers, the values for these three streams are high. For example, Rasera et al. (2008)RASERA, M. F. F. L; BALLESTER, V. M.; KRUSCHE, A. V.; SALIMON, C.; MONTEBELO, L. A.; ALIN, S. R. et al. Estimating the Surface Area of Small Rivers in the Southwestern Amazon and Their Role in CO2 Outgassing. Earth Interactions, v. 12, n. 6, p. 1-16, 2008. https://doi.org/10.1175/2008EI257.1
https://doi.org/10.1175/2008EI257.1... estimated CO₂ fluxes from third- and fourth-order rivers in the Ji-Paraná River Basin that ranged from 0.67 ± 0.08 to 12.63 ± 1.49 μmol CO₂ m⁻² s⁻¹ at Arenito and Miolo Rivers, respectively, with an average of 5.49 ± 3.16 μmol CO₂ m⁻² s⁻¹. It is remarkable, then, that the Cumaru, São João and Pachibá Streams, principally in the headwater area, had similar CO₂ evasion fluxes per unit area as even the largest CO₂-emitting Amazonian rivers.

4. CONCLUSIONS

The results of this study support the hypothesis that small streams in the Amazon can have high rates of CO₂ evasion, particularly in the headwater region. The results of this study are unique in demonstrating these high rates within the matrix of small family farm management within these catchments. Despite over 100 yrs. of forest disturbance and use, the mixed secondary vegetation is an important component driving an abundant and vigorous carbon cycle.

5. REFERENCES

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