SOIL ORGANIC CARBON, CARBON STOCK AND THEIR RELATIONSHIPS TO PHYSICAL ATTRIBUTES UNDER FOREST SOILS IN CENTRAL AMAZONIA

Marques, Jean Dalmo de Oliveira; Luizão, Flávio Jesus; Teixeira, Wenceslau Geraldes; Vitel, Claudia Marie; Marques, Elizalane Moura de Araújo

doi:10.1590/0100-67622016000200002

ABSTRACT

The soil carbon under Amazonian forests has an important roles in global changing, making information on the soil content and depths of these stocks are considerable interest in efforts to quantify soil carbon emissions to the atmosphere.This study quantified the content and soil organic carbon stock under primary forest up to 2 m depth, at different topographic positions, at Cuieiras Biological Reserve, Manaus/ ZF2, km 34, in the Central Amazon, evaluating the soil attributes that may influence the permanence of soil carbon. Soil samples were collected along a transect of 850 m on topographic gradient Oxisol (plateau), Ultisol (slope) and Spodosol (valley). The stocks of soil carbon were obtained by multiplying the carbon content, soil bulk density and trickiness of soil layers. The watershed was delimited by using STRM and IKONOS images and the carbon contend obtained in the transects was extrapolated as a way to evaluate the potential for carbon stocks in an area of 2678.68 ha. The total SOC was greater in Oxisol followed by Spodosol and Ultisol. It was found direct correlations between the SOC and soil physical attributes. Among the clay soils (Oxisol and Ultisol), the largest stocks of carbon were observed in Oxisol at both the transect (90 to 175.5 Mg C ha^-1) as the level of watershed (100.2 to 195.2 Mg C ha^-1). The carbon stocks under sandy soil (Spodosol) was greater to clay soils along the transect (160-241 Mg C ha^-1) and near them in the Watershed (96.90 to 146.01 Mg C ha^-1).

Keywords:
Carbon; Soil physical properties; Amazonian forest

RESUMO

O carbono do solo sob floresta amazônica tem um papel importante na mudança global, tornando as informações sobre os teores de carbono e profundidades desses estoques são de grande interesse no esforço de quantificar as emissoes de carbono do solo para a atmosfera. Este estudo quantificou os teores e estoques de carbono orgânico do solo sob floresta primária até 2 m de profundidade, em diferentes posições topográficas, na Reserva Biológica do Cueiras, Manaus/ZF2, km34, na Amazônia Central; avaliando-se os atributos do solo que podem influenciar na permanência do carbono no solo. Coletaram-se amostras de solos ao longo de um transecto de 850 m num gradiente topográfico Latossolo (platô), Argissolo (vertente) e Espodossolo (baixio). Os estoques de carbono do solo foram obtidos multiplicando a concentração de carbono pela densidade do solo e espessura de camadas do solo. Delimitou-se uma microbacia hidrográfica através de imagens STRM e IKONOS extrapolando-se os teores de carbono obtidos no transecto como forma de avaliar o potencial de estocagem de carbono em uma área de 2.6 78,68 ha. O total de COS foi maior no Latossolo seguido do Espodossolo e Argissolo. Encontrou-se correlações diretas entre o COS e atributos físicos dos solos. Entre os solos argilosos (Latossolo e Argissolo), os maiores estoques de carbono foram observados sob Latossolo tanto a nível de transecto (90 a 175,5Mg ha^-1 de C) quanto a nível de área da microbacia (100,2 a 195,2 Mg ha^-1 de C). O estoque de carbono sob solo arenoso (Espodossolo/baixio) foi superior aos solos argilosos ao longo do transecto (160 a 241 Mg ha^-1 de C) e próximo a eles na microbacia hidrográfica (96,90 a 146,01 Mg ha^-1 de C).

Palavras-chave:
Carbono; Propriedades físicas do solo; Floresta Amazônica

1. INTRODUÇÃO

Changes in tropical natural ecosystems may cause reductions in carbon inputs depending of the use, management, physical, chemical and biological soil (SILVA JUNIOR et al., 2009SILVA JÚNIOR, M.L.S.; DESJARDINS, T.; SARRAZIN, M.; MELO, V.S.; MARTINS, P.F.S.; SANTOS, E.R.; CARVALHO, C.J.R. Carbon content in amazonian oxisols after forest conversion to pasture. Revista Brasileira de Ciência do Solo, v.33, n.6, p.1603-1611, 2009.).

The soil kept in natural conditions, under native vegetation, show physical characteristics suitable for the optimal development of plants (SPERA et al., 2004SPERA, S.T.; SANTOS, H.P.; TOMM, G.O.; FONTANELI, R.S. Avaliações de alguns atributos físicos de solo em sistemas de produção de grãos, envolvendo pastagens sob plantio direto. Revista Científica Rural, v.9, n.1, p.23-31, 2004.). However, when native ecosystems are changed, the dynamic balance is broken and, usually, causing lower carbon inputs than outputs, leading to reduction in the amount and alteration of quality SOM (soil organic matter) (CERRI et al., 2008CERRI, C.E.P.; FEIGL, B.; CERRI, C.C. Dinâmica da matéria orgânica do solo na Amazônia. In: SANTOS, G.A.; SILVA, L.S.; CANELLAS, L.P.; CAMARGO, F.O. (Ed.). Fundamentos da matéria orgânica do solo: ecossistemas tropicais e subtropicais. 2.ed. Porto Alegre: Metrópole, 2008. p.325-358.).

Factors such as original vegetation, type and soil management, climate, quantity and quality of plant residues (COSTA et al, 2009COSTA, O.V.; CANTARUTTI, R.B.; FONTES, L.E.F.; COSTA, L.M.; NACIF, P.G.S.; FARIAS, J.C. Estoque de carbono do solo sob pastagem em área de Tabuleiro Costeiro no sul da Bahia. Revista Brasileira de Ciência do Solo, v.33, p.1137-1145, 2009.;. MAIA et al., 2009MAIA, S.M.F.; OGLE, S.M.; CERRI, C.E.P.; CERRI, C.C. Effect of grassland management on soil carbon sequestration in Rondônia and Mato Grosso states, Brazil. Geoderma, v.149, n.1, p.84-91, 2009.; FRAZÃO et al., 2010FRAZÃO, L.A.; SANTANA, I.K.S.; CAMPOS, D.V.B.; FEIGL, B.J.; CERRI, C.C. Estoques de carbono e nitrogênio e fração leve da matéria orgânica em Neossolo Quartzarênico sob uso agrícola. Pesquisa Agropecuária Brasileira, v.45, p.1198-1204, 2010.), texture (LUCA et al., 2008LUCA, E.F.; FELLER, C.; CERRI, C.C.; BARTHÈS, B.; CHAPLOT, V.; CAMPOS, D.C.; MANECHINI, C. Avaliação de atributos físicos e estoques de carbono e nitrogênio em solos com queima e sem queima de canavial. Revista Brasileira de Ciência do Solo, v.32, n.2, p.789-800, 2008. ), mineralogy (ZINN et al., 2007ZINN, Y.L.; LAL, R.; BIGHAM, J.M.; RESCK, D.V.S. Edaphic controls on soil organic carbono retention in the Brazilian Cerrado: Texture and mineralogy. Soil Science Society of America Journal, v.71, p.1204-1214, 2007.) and soil bulk density (NAVARRETE; TSUTSUKI, 2008NAVARRETE, I.; TSUTSUKI, K. Land-use impact on soil carbon, nitrogen, neutral sugar composition and related chemical properties in a degraded Ultisol derived from volcanic materials in Leyte, Philippines. Soil Science and Plant Nutrition, v.54, p.321-331, 2008.) have been described as controlling the magnitude and speed of changing in the content and quality of SOM.

The current concern is for studies which quantify the changes in content and carbon stocks in areas oftraditional agriculture (SERGNINI et al., 2013SEGNINI, A.; CARVALHO, J.L.N.; BOLONHEZI, D.; MILORI, D.M.B.P.; SILVA, W.T.L.; SIMÕES, M.L.; CANTARELLA, H.; MARIA, I.C.; MATIN-NETO, L. Carbon stock and humification índex of organic matter affected by sugarcane straw and soil management. Scientia Agrícola, v.70, p.321-326, 2013.; CERRI et al., 2013CERRI, C.E.P.; GALDOS, M.V.; CARVALHO, J.L.N.; FEIGL, B.J.; CERRI, C.C. Quantifying soil carbon stocks and greenhouse gas fluxes in the surgarcane agrosystem: point of view. Scientia Agricola, v.70, p.361-368, 2013.), as well as the mensuration carbon losses in Amazonian soils due the replacement of native forest for pasture (DESJARDINS et al., 2004DESJARDINS, T.; BARROS, E.; SARRAZIAN M.; GIARDINA, C.; MARIOTTI, A. Effects of forest conversion to pasture on soil carbon content and dynamics in Brazilian Amazon. Agriculture Ecosystems & Environment, v.103, n.2, p.365-373, 2004.; COSTA et al., 2009COSTA, O.V.; CANTARUTTI, R.B.; FONTES, L.E.F.; COSTA, L.M.; NACIF, P.G.S.; FARIAS, J.C. Estoque de carbono do solo sob pastagem em área de Tabuleiro Costeiro no sul da Bahia. Revista Brasileira de Ciência do Solo, v.33, p.1137-1145, 2009.;. SILVA JÚNIOR et al., 2009SILVA JÚNIOR, M.L.; DESJARDINS, T.; SARRAZIN, M.; MELO, V.S.; MARTINS, P.F.; SANTOS, E.R.; CARVALHO, C.J.R. Carbon content in Amazonian Oxisols after Forest conversion to pasture. Revista Brasileira de Ciência do Solo, v.33, p.1603-1611, 2009.).

Due to its size, characteristics, natural and anthropogenic processes, the Amazon can significantly modify the carbon stocks and water between the biosphere and atmosphere (MARLAND et al., 2008MARLAND, G.R.J.; ANDRÉS, T.A.; BODEN, C.; BRENKERT, A. Global, regional and national annual CO2 emissions estimates from fossil fuel burning, cement production and gas flaring. 1751-1998 (revised in august, 2003), Rep. ORNL/CDIAC/NDP-030, Oak Ridge Natl. Lab., Oak Ridge, Tenn., 2008. [ Acesso em: 20 set. 2008]. Disponível em: http://cdiac.esd.ornl.gov/ndps/ndp030.html.
http://cdiac.esd.ornl.gov/ndps/ndp030.ht... ). Thus, carbon study in the soil under primary forest in the Amazon provides a contribution in the field of scientific knowledge through the provision of data about the content and carbon stocks in environmental conservation areas, whereas current studies emphasize only cultivated areas. In addition, part of the estimates about the amount of carbon stored as organic matter, in Amazon soils, in areas of difficult access, based on profile data collected by Radambrasil project between 1973-1986.

The knowledge about carbon and soil physical properties are extremely important to determine management practices which keep carbon in the terrestrial environment and appropriate forms of soil conservation in tropical forests. The latest information on carbon stored in the soil has been used in mathematical models in order to predict potential emissions to the atmosphere and as a way to assess the environmental quality of forest ecosystems.

Therefore, it is necessary to examine the Amazon soils with capacity to store or lose carbon, which, in turn, requires understanding how much of carbon is stored in soils and how quickly it can be stabilized or destabilized. In this context, quantified the content and soil organic carbon stocks under primary forest, up to 2 m depth, at different topographic positions, evaluating soil attributes that may influence the permanence of carbon in soil.

2. MATERIALS AND METHODS

The study area is located in the Cuieiras Biological Reserve of the Instituto Nacional de Pesquisas da Amazônia (INPA). The reserve covers an area of approximately 22.700 ha, located 60 km north of Manaus, Amazonas, Brazil. The site is at kilometer 34 on the ZF-2 service road (approximate geographical coordinates: 2°35'21.08''98 S and 60° 6'53.63''W). Vegetation in the reserve is "dense ombrophilous forest". That is considered to be primary (not disturbed by non-indigenous occupation). The reserve is distributed between two basins: the Cuieiras River basin (13,414 ha) to the West and theTarumã-Açu River basin (9321 ha) to the East (RANZANI, 1980). The topography of the transect included in this study covers a sequence of plateau, slope and valley bottom (Luizão et al., 2004LUIZÃO, R.C.C.; LUIZÃO, F.J.; PAIVA, R.Q.; MONTEIRO, T.F.; SOUZA, L.S.; KRUIJT, B. Variation of carbon and nitrogen cycling processes along a topographic gradient in a central Amazonian forest. Global Change Biology, v. 22 , p.592-600, 2004.). The experiment was conducted in topographic transect of 850 m consisting of plateau, slope and valley.

Nine permanent plots (with dimension 20 x 40 m), being three each topographical position, for successive collections of soil samples from 2005 to 2010, one collection, every year, in the same period. Soil samples were collected along a transect of850 m, in pedological horizons, by opening soil profiles and standards areas during the collection period. The profiles had dimensions of 1.5 m x 1.5 m x 2.0 m. The identification of horizons and morphological description were performed according to Santos et al. (2015)SANTOS, R.D.; LEMOS, R.C.; SANTOS, H.G.; KER J.C.; ANJOS, L.H. Manual de descrição e coleta de solos no campo. 5.ed. Viçosa, MG: Sociedade Brasileira de Ciência do Solo, 2005. 100p..

The granulometric analysis and density of the particles were measured using the pipette and pycnometer methods, according EMBRAPA (1997)EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Manual de métodos de análise de solo. 2.ed. Rio de Janeiro: 1997. 212p. (Embrapa-CNPS. Documentos; 1)., respectively. The soil bulk density was determined in undeformed samples, collected with Uhland sampler, in volumetric rings (height 0.05 m and diameter 0.05 m) along the selected layers in five replications.

The determination of the pore size distribution by size was obtained from the samples used for obtaining bulk density, with separation between macro and micropores, by drainage, at 10 kPa pressure. Total porosity was calculated by the relationship between soil bulk density and particle density.

For determination of carbon content used the Fisons Instruments analyzer NC NA 1500, using approximately 25-30 mg of material previously macerated in a mortar and passed at 21,2 cm mesh sieve, in order to reduce errors associated the grain size.

The soil carbon stocks were calculated by multiplying the carbon content by soil bulk density and the thickness of the sampled soil layer (BERNOUX et al., 1998BERNOUX, M.; ARROUAYS, D.; CERRI, C.C.; BOURENNANE, H. Modelling vertical distribution of carbon in Oxisols of the Western Brazilian Amazon (Rondônia). Soil Science, v.163, p.941-951, 1998.), considering:

E = ρ_sxAxC

where E is the carbon stock (Mg.ha^-1); p_s, the soil bulk density (g cm^-3); A, the thickness of the sampled soil layer (cm) and C, carbon content in the soil (%).

The soil carbon stocks were determined in the layers: 0-40 cm, 0-100 cm and 0-200 cm in plateau (Oxisol) and slope (Ultisol). The values of soil carbon stocks were corrected by mass equivalency of the reference area (SISTI et al., 2004SISTI, C.P.J.; SANTOS, H.P.; KOHHAN, R.; ALBES, B.J.R.; URQUIAGA, S.; BODEY, R.M.. Change in carbon and nitrogen stocks in soil under 13 years of conventional or zero tillage in southern Brazil. Soil and Tillage Research, v.76, n.1, p.39-58, 2004.).

Under valley soil, the stocks were calculated for the depths: 0-25 cm and 0-120 cm due to the intensity of roots on the soil surface and by interference of the water table height.

The values of soil carbon stock were extrapolated for a Igarapé Açu Watershed, with 2.678.68 ha, belonging to the hydrography of Cueiras in order to estimate the total carbon stock, using the hydrological function of arcgis 9.0 software. With the image STRM (Shuttle Radar Topographic M) 30m accumulations and directions of flows were calculated, allowing the delimitation of the area. Then the STRM and IKONOS images were randomized and using the points collected by the GPS delimited three topographical classes: plateau, slope and valley. It was considered the plateau area with an altitude of between 90-120 m, slope between 7590 m and valley between 50-75 m. Thus, it were calculated the areas corresponding to three distinct classes defined by plateau (41.5%), slope (35.8%) and valley (22.6%) (Figure 1), being possible to estimate the total carbon stock potential considering the soil classes identified along the transect to two meters depth.

Figure 1
Picture of the watershed boundary with the demarcation of areas plateau, slope and valley.
Figura 1
Imagem da bacia hidrográfica com as delimitações das áreas de platô, vertente e baixio.

The carbon data, physical attributes, soil carbon stocks (850 m/transect) and total carbon stocks (2678.68 ha) were subjected to analysis of variance and means were compared by 5% Tukey test. Analysis Pearson correlations were performed to relate SOC to soil physical attributes.

3. RESULTS

The soils were classified as oxisol (plateau), ultisol (slope) and spodosol (valley) according to (SOIL SURVEY STAFF, 1998). On the plateau (oxisol), the granulometric analysis revealed clay contents of 687 g kg^-1, on the surface, and of 852 g kg^-1 until 2 m depth, indicating a very clay texture (Table 1). The ultisol (slope) showed a sandy clay loam textured on surface with 301 g kg^-1, increasing in depth to 497.63 g kg^-1, caracterized a clay texture. The spodosol (valley) had a different dynamic, containing clay content between 9 g kg^-1 to 18 g kg^-1 caracterized sandy texture. The soil bulk density increases with depth, ranging from 1.05 g cm^-3 to 1.22 g cm^-3 in oxisol increasing in the ultisol ranging from 1.20 g cm^-3 to 1.42 g cm^-3 and Spodosol from 1.45 g cm^-3 to 1.72 g cm^-3. The fractionation of pores showed the oxisol with high porosity (> 0.50 m^-3m^-3) with predominantly micropores (> 0.40 m^-3m^-3) and macropores from 0.03 to 0.12 m^-3m^-3. The increased macroporosity in the ultisol ranging from 0.12 m^-3m^-3 to 0.22 m^-3m^-3. The spodosols showed a increase in the macroporosity (0.33 m^-3m^-3 to 0.39 m^-3m^-3), due to the increase of coarse sand particles (Table 1).

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Table 1
Soil physical attributes in the transect of the Cueiras Biological Reserve, Manaus, AM
Tabela 1
Atributos físicos dos solos no transecto na Reserva Biologica do Cuieiras, Manaus, AM

The carbon content decreased with increasing depth in both soils, with the highest levels found in the soil surface (Table 1). The oxisol (plateau) showed carbon content from 0.34 to 2.97%, the ultisol (slope) from 0.21 to 2.31% and the Spodosol (valley) from 0.52 to 4.37%, according with the findings by Luizão et al. (2004)LUIZÃO, R.C.C.; LUIZÃO, F.J.; PAIVA, R.Q.; MONTEIRO, T.F.; SOUZA, L.S.; KRUIJT, B. Variation of carbon and nitrogen cycling processes along a topographic gradient in a central Amazonian forest. Global Change Biology, v. 22 , p.592-600, 2004.. On the surface, Spodosol showed carbon content higher than most clay soils (oxisols and ultisols) (Table 1), in contrast with the results of Luizão et al. (2004)LUIZÃO, R.C.C.; LUIZÃO, F.J.; PAIVA, R.Q.; MONTEIRO, T.F.; SOUZA, L.S.; KRUIJT, B. Variation of carbon and nitrogen cycling processes along a topographic gradient in a central Amazonian forest. Global Change Biology, v. 22 , p.592-600, 2004. who obtained 0.5% to 1.0% (5 cm) and 0.2 to 0.8 (10 cm), perhaps due the dynamic valley area, that is influenced by fluctuations in the water table height and by action of the thin roots in the soil surface, providing carbon in higher concentrations in the superficial layers. In Spodosol it is common the accumulation of the organic matter on surface, resulting humification process (SARMIENTO et al., 2005SARMIENTO, G; PINILLOS, M.; GARAY, I. Biomass variability in tropical American lowland rain forests. Ecotropics, v.18, n.1, p.1-20, 2005.) due the high diversity of litter on the system (NAVARRETE; TSUTSUKI, 2008NAVARRETE, I.; TSUTSUKI, K. Land-use impact on soil carbon, nitrogen, neutral sugar composition and related chemical properties in a degraded Ultisol derived from volcanic materials in Leyte, Philippines. Soil Science and Plant Nutrition, v.54, p.321-331, 2008.), with high amount of lignin (STALLCUP et al., 2006STALLCUP, L.A.; ARDÓN, M.; PRINGLE, C.M. Does nitrogen become limiting under high-P conditions in detritus-based tropical streams? Freshwater Biology, v.51, p.1515-1526, 2006.) associated a slow rate of decomposition (LUIZÃO et al., 2004LUIZÃO, R.C.C.; LUIZÃO, F.J.; PAIVA, R.Q.; MONTEIRO, T.F.; SOUZA, L.S.; KRUIJT, B. Variation of carbon and nitrogen cycling processes along a topographic gradient in a central Amazonian forest. Global Change Biology, v. 22 , p.592-600, 2004.) due preference feed shredders invertebrates, microbial decomposition and susceptibility physical fragmentation (GRAÇA; ZIMMER, 2005GRAÇA, M.A.S.; ZIMER, M. Leaf toughness. In: GRAÇA, M.A.S.; BÀRLOCHER, F.; GESSNER, M.O. (Ed.). Methods to study litter decomposition: a pratical guide. New York: Springer, 2005. p.109-113.).

We found direct correlations between SOC and soil bulk density, clay content, porosity, macroporosity and microporosity (Table 2), confirming that these soil properties may interfere in the SOC. Positive correlation was obatained between SOC and macroporosity (r = 0.60) and total porosity (r = 0.82) on the plateau (oxisol); with total porosity (r = 0.87), macroporosity (r = 0.72) and microporosity (r = 0.61) in the valley (spodosol); negative relationshiphs were found with clay content (r = - 0.87) in oxisol and ultisol (r = - 0.81), soil bulk density on the plateau (oxisol) (r = - 0.81), slope (ultisol) (r = - 0.80) and valley (Spodosol) (r = - 0.80) with micropores on the plateau (Oxisol) (r = - 0.71) and slope (Ultisol) (r = - 0.60) (Table 2).

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Table 2
Pearson correlation coefficient between attributes and soil carbon contents (n = 5)
Tabela 2
Coeficiente de correlação de Pearson entre Atributos do solo e os teores de carbono (n=5).

The table 3 shows the total carbon stocks up to 2.0 m depth along the layers 0-40, 0-100 and 0-200 cm belonging to transect Igarapé Açu Watershed (Cuieiras Biological Reserve Cueiras/ZF2). Despite the carbon decrease with depth (Table 1), stocks did not follow this trend, due to the increase of soil bulk density in depth and thickness of soil horizons. Among the clay soil (oxisol/plateau and ultisol/slope), the largest carbon stocks were observed under oxisol in both areas studied (90 to 175.5 Mg ha^-1 of C in the 850 m transect) and (100,2 to 195.2 t ha^-1 of C in the Igarapé Açu Watershed). The carbon stocks in sandy soils (spodosol/valley) were higher than clay soils along the transect (160 to 241 Mg ha^-1 of C) and almost these soils in the Igarapé Asu Watershed (96.902 to 146.018 Mg ha^-1 of C).

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Table 3
Mean values of carbon stocks (Mg C ha^-1) obtained over 5 years of sampling
Tabela 3
Valores médios dos estoques de carbono (Mg ha^-1de C) obtidos ao longo de 5 anos de amostragem

4. DISCUSSION

Variations in physical attributes of soils along the topographical gradient under primary forest influence content and carbon stock. The studied soils have a greater capacity to store carbon in depth. The largest carbon content obtained in surface layers are explained due the surface soil suffer greater interference of organic matter deposited by forest. Oliveira et al. (2008)OLIVEIRA, J.T.; SANTOS, A.M. S.; MOREAU, A.M.; MENEZES, A.A.; COSTA, O.V. Características físicas e carbono orgânico de solos sob diferentes tipos de uso da terra. Revista Brasileira de Ciência do Solo, v.32, n.1, p.132-138, 2008. emphasize that the soil surface layers are more sensitive to variations of carbon due to the action of microorganisms in the SOM.

With depht increase, it is obtained an increase in clay content and a decrease of organic carbon in the soil due the reduced contact with the surface layers (Table 1), resulting in negative correlations between carbon and clay content (Table 2). The increase in microporosity content and soil bulk density in depth coincide with lower carbon contents, causing negative correlations (Table 2), whereas the higher macropore content relate to increases in carbon content and provided positive correlations (Table 1 and 2).

The correlations between carbon content and soil physics attributes found in this research has been observed in other recent studies (ZINN et al., 2007ZINN, Y.L.; LAL, R.; BIGHAM, J.M.; RESCK, D.V.S. Edaphic controls on soil organic carbono retention in the Brazilian Cerrado: Texture and mineralogy. Soil Science Society of America Journal, v.71, p.1204-1214, 2007.; COSTA et al., 2008COSTA, F.S.; BAYER, C.; ZANATTA, J.A.; MIELNICZUK, J. Estoques de carbono orgânico no solo e emissões de dióxido de carbono influencia das por sistemas de manejo no sul do Brasil. Revista Brasileira de Ciência do Solo, v.32, n.1, p.323-332, 2008.;. MARQUES et al., 2008MARQUES, J.D.O.; TEIXEIRA, W.G.; REIS, A.M.; CRUZ JUNIOR, O.F.; MARTINS, G.C. Avaliação da condutividade hidraulica do solo saturada utilizando dois métodos de laboratório numa topossequência com diferentes coberturas vegetais no Baixo Amazonas. Acta Amazônica, v.38, n.1, p.193-206, 2008.; LANZANOVA et al., 2010LANZANOVA, M.E.; ELTZ, F.L.F.; NICOLOSO, R.; AMADO, T.J.C.; REINERT, D.J.; ROCHA, M.R. Atributos físicos de um Argissolo em sistemas de culturas de longa duração sob semeadura direta. Revista Brasileira de Ciência do Solo, v.34, n.4, p.1333-1342, 2010.; CALONEGO et al., 2012CALONEGO, J.C.; SANTOS,C.H.; TIRITAN, C.S.; CUNHA JÚNIOR, J.R. Estoques de carbono e propriedades físicas de solos submetidos a diferentes sistemas de manejo. Revista Caatinga, v.25, n.2, p.128-135, 2012.; HICKMANN et al., 2012HICKMANN, C.; COSTA, L.M.; SCHAEFER, C.E.G.R.; FERNANDES, R.B.A.; ANDRADE, C.L.T. Atributos físico-hidricos e carbono orgânico de um argissolo após 23 anos de diferentes manejos. Revista Caatinga, v.25, n.1, p.128-136, 2012.;. CHAUDHARI et al., 2013CHAUDHARI, P.R.; AHIRE, D.V.; AHIRE, V.D.; CHKRAVARTY, M.; MAITY, S. Soil bulk density as related to soil texture, organic matter content and available total nutrients of coimbatore soil. International Journal of Scientific and Research Publications, v.3, p.2250-3153, 2013.;. HUGAR; SORAGANVI, 2014HUGAR, G.M.; SORAGANVI, V.S. Impact of soil organic carbon on bulk density and plasticity index of arid soils of Raichur, India. International Research Journal of Environment Sciences, v.3, n.2, p.48-58, 2014.). Although the carbon content decrease in depth, physical attributes of Amazon soils such as clay content, soil bulk density, amount of macropores and micropores may exert the protection of the carbon contained in the soil (MARQUES et al., 2010MARQUES, J.D.O.; TEIXEIRA, W.G.; REIS, A.M.; CRUZ JUNIOR, O.F.; BATISTA, S.M.; AFONSO, M.A.C.B. Atributos químicos, físico-hídricos e mineralogia da fração argila em solos do Baixo Amazonas: Serra de Parintins. Acta Amazônica, v.40, n.1, p.1-12, 2010., 2012MARQUES, J.D.O.; LUIZÃO, F.J.; TEIXEIRA, W.G.; FERREIRA, S.J.F. Variações do carbono orgânico dissolvido e de atributos físicos do solo sob diferentes sistemas de uso da terra na Amazônia Central. Revista Brasileira de Ciência do Solo, v.36, n.2, p.611-622, 2012.) leading to increases in carbon stocks in depth.

The reduced macroporosity and high microporosity in depth on the plateau (Oxisol) assist in carbon retention in the subsurface horizon, allowing for greater stability. On the other hand, the valley soils (Spodosol), due to higher percentage of sand, are more unstable in the soil carbon maintenance that may be released to the atmosphere more easily if the soil is changed.

It is found a greater correlation between carbon content with soil structure represented by pore distribution in the soil, probably caused by aggregation of the SOM with clay particles forming micro and macro aggregates, which may cause physical barrier to carbon decomposition. The positive and negative correlations found (Table 2), shows the importance of organic matter how soil structural component, being considered an efficient soil quality indicator, because it is sensitive to management changes and exert influence on the soil microbial activity (RAMOS et al., 2010RAMOS, F.T.; MONARI,YC.; NUNES, M.C.M.; CAMPOS, D.T.S.; RAMOS, D.T. Indicadores de qualidade em um Latossolo Vermelho-Amarelo sob pastagem extensiva no pantanal matogrossense. Revista Caatinga, v.23, n.1, p.112-120, 2010.). The structure of Amazonian soils under forest allows carbon to remain stored, avoiding losses to the atmosphere. Modifications in these attributes may cause major changes in content and carbon stocks.

Other studies have shown the behavior of SOC in depth, emphasizing that the total carbon stored below 1 m may actually be higher than the carbon stock above 1m (NEPSTAD et al., 1994NEPSTAD, D.C.; CARVALHO, C.R.; DAVIDSON, E.A.; JIPP, P.H.; LEFEBVRE, G.H.; NEGREIROS, E.D.; SILVA, T.A.; STONE, S.E.; TRUMBORE, S.E.; VIEIRA, S. The role of deep roots in the hydrological cycles of Amazonian forests and pastures. Nature, v.372, p.666-669, 1994.; TRUMBORE et al., 1995TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995. ). Nepstad et al. (1994)NEPSTAD, D.C.; CARVALHO, C.R.; DAVIDSON, E.A.; JIPP, P.H.; LEFEBVRE, G.H.; NEGREIROS, E.D.; SILVA, T.A.; STONE, S.E.; TRUMBORE, S.E.; VIEIRA, S. The role of deep roots in the hydrological cycles of Amazonian forests and pastures. Nature, v.372, p.666-669, 1994. were the first to emphasize the importance of carbon in depth under tropical forest soils. Conducted studies in Pará showed that the forest soil below the depth of 1 m contained more carbon than biomass on the surface, attributing this behavior to the thickness of the subsurface horizons and roots activity.

The amount of carbon stored in the subsurface horizons may occur due to the slow movement of SOM in the Bw horizons when compared to the surface Ap horizons. The clayey texture or very clayey in depth and distribution of pores cause an accumulate of carbon over the years (JONES et al., 2005JONES, C.C.; MCCONNELL, K.; COLEMAN, P.; COX, P.; FALOON, P.; JENKINSON, D.; POWLSON, D. Global climate change and soil carbon stocks; predictions from two contrasting models for the turnover of carbon in soils. Global Change Biology, v.11, n.1, p.114-166, 2005.; LORENZ; LAL, 2005LORENZ, K.; LAL, R. The depth distribution of soil organic carbon in relation to land use and management and the potential of carbon sequestration in subsoil horizons. Advanced Agronomy, v.88, n.1, p.35-66, 2005.).

In recent years, research concerning dynamics and carbon in the soil is limited to a few areas, of sparse periods in time, some, without setting depths, with units of different magnitudes and without precise sampling of soil bulk density (Table 4). Carbon stock estimates in tropical soils and in the Amazonian region have been executed in different locations, with results also very varied (Table 4). A comparison could only be from the same units of mass and area which is impeded by different studied dephts.

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Table 4
Studies on carbon stocks in tropical soils.
Tabela 4
Estudos realizados sobre estoque de carbono em Solos Tropicais

The results of this study are agree to those observed in some studies to Amazon soils (SOMMER et al., 2000SOMMER, R.; DENICH, M.; VLEK, P.L.G. Carbon storage and root penetration in deep soils under small-farmer land-use systems in the Eastern Amazon region, Brazil. Plant and Soil, v.219, p.231-241, 2000.), equivalent to those of other forest soils in tropical regions (VELDKAMP et al., 2003VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.), above (SALIMON, 2007SALIMON, C.I.; WADI, P.G.S.; MELO, A.W.F. Dinâmica do carbono na conversão de floresta para pastagens em argissolos da formação geológica solimões, no sudoeste da Amazônia. Revista de Biologia e Ciências da Terra, v.7, n.1, p.29-38, 2007. ) and below (POTTER et al., 1998POTTER, C.S.; DAVIDSON, E.A.; KLOOSTER S.A.; NEPSTAD, D.C.; NEGREIROS, G.H.; BROOKS, V. Regional application of an ecosystem production model for studies of biogeochemistry in Brazilian Amazonia. Global Change Biology, v.4, p.315-333, 1998.) other conducted studies in other areas of the Amazon. Recent review of carbon stock in the first 0.5 and 1.0 m depths estimated values between 55.7 and 95.7 t Cha^-1, respectively. This behavior has also been observed in other studies ranging from 0.1 to 208.7 t C ha^-1 at 0.5 m depth and from 95.7 to 250.5 t C ha^-1 m depth (IBGE, 2012INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA - IBGE. Maior estoque de carbono da região da Amazônia Legal está no solo. [acesso em: 27 jul. 2012] Disponível em: http://www.ibge.gov.br/home/.
http://www.ibge.gov.br/home/... ), similar to those in this study. The differences between the results in this study (Table 3) and other published data (Table 4) are related to soil type, location, size of the sampling area, magnitude unit, collected depths, soil horizon thickness, soil bulk density (estimated or determined), soil type, vegetation type and topographic position (Table 4).

The results of this study confirm the reported Fearnside (2006)FEARNSIDE, P.M. Mitigation of climatic change in the Amazon. In: LAURANCE, W.F.; PERES, C.A. (Ed.) Emerging threats to tropical forests. Chicago: University of Chicago Press, 2006. p.353-375., providing that a removal Amazonian forest would contribute to a significant feedback, intensifying the greenhouse effect, both by the release of forest biomass carbon (HUNTINGFORD et al., 2004HUNTINGFORD, C.; HARRIS, P.O.; GEDNEY, N.; COX, P.M.; BETTS, R.A.; MARENGO, J.A.; GASH, J.H.C. Using a GCM analogue model to investigate the potential for Amazonian forest dieback. Theoretical and Applied Climatology, v.78, n.1, p.177-185, 2004.) as by the release of soil carbon (JONES et al., 2005JONES, C.C.; MCCONNELL, K.; COLEMAN, P.; COX, P.; FALOON, P.; JENKINSON, D.; POWLSON, D. Global climate change and soil carbon stocks; predictions from two contrasting models for the turnover of carbon in soils. Global Change Biology, v.11, n.1, p.114-166, 2005.). Despite information of the potential to sequester carbon is faster in the tropics, mainly in vegetation, to a lesser extent, in the surface layers of the soil, the results showed the potential of the soils studied to store carbon. Although there are not enough information about the potential changes in the soil at great depths (MUTUAL et al., 2005MUTUO, P.K.; CADISCH, G.; ALBRECHT, A.; PALM, C.A.; VERCHOT, L. Potential of agroforestry for carbon sequestration and mitigation of greenhouse gás emissions from soils in the tropics. Nutrient Cycling in Agroecosystems, v.71, n.1, p.43-54, 2005.), the studied soil classes have physical attributes which can contribute positively to the carbon protection on the soil.

5. CONCLUSIONS

The soils under Amazonian forests, along the topographic gradient, has great potential to store carbon in depth, being influenced by soil physical properties, soil type and landscape position.

The oxisol has the highest carbon content up to 2.0 depth, followed by spodosol and ultisol.

The Spodosol has large stock of carbon up to 120 cm produndidade, which can be easily lost in exploitative situations because the soil is sandy.

These results suggests the need for preservation of soils under tropical Forest because changes in forest cover would decrease content and carbon stocks.

6. ACKNOWLEDGEMENTS

The authors would like to thank the LBA, PELD, PPG7 Project, and the CNPq for financial support.

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Publication Dates

Publication in this collection
Mar-Apr 2016

History

Received
12 Apr 2013
Accepted
09 Dec 2015

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[1] BALSEIRO, E.; ALBARINO, R. C-N mismatch in the leaf litter-shredder relationship of an Andean Patagonian stream detritivore. Journal of the North American Benthological Society, v. 25, p.607-615, 2006.

[2] BERNOUX, M.; ARROUAYS, D.; CERRI, C.C.; BOURENNANE, H. Modelling vertical distribution of carbon in Oxisols of the Western Brazilian Amazon (Rondônia). Soil Science, v.163, p.941-951, 1998.

[3] CALONEGO, J.C.; SANTOS,C.H.; TIRITAN, C.S.; CUNHA JÚNIOR, J.R. Estoques de carbono e propriedades físicas de solos submetidos a diferentes sistemas de manejo. Revista Caatinga, v.25, n.2, p.128-135, 2012.

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Soils	Depht	Clay	Silt	Total sand	ρ	Carbon	Pt	Ma	Mi
Soils	(cm)	................(gkg-¹)................			(g cm^-3)	(%)	................(m³m^-3)................
Oxisol (Plateau)	0-10	687,08 c	64,18 a	248,73 a	1,05 c	2,97 a	0,55 a	0,12 a	0,42 c
	10-45	819,46 a	27,20 c	153,33 c	1,22 a	1,36 b	0,48 b	0,03 c	0,45 b
	45-82	788,66 b	17,25 d	194,08 b	1,19 b	0,65 c	0,52 a	0,06 b	0,45 b
	82-108	855,37 a	15,50 d	129,11 d	1,22 a	0,52 d	0,52 a	0,05 b	0,47 a
	108-200⁺	852,79 a	38,10 b	109,10 e	1,22 a	0,34 e	0,53 a	0,05 b	0,47 a
Ultisol (Slope)	0-14	301,01 d	74,86 a	624,12 a	1,20 b	2,31 a	0,49 b	0,21 a	0,28 d
	14-38	422,45 c	44,77 d	532,77 b	1,30 a	1,00 b	0,45 b	0,12 d	0,32 ab
	38-59	478,24 b	47,20 d	474,53 c	1,34 a	0,57 c	0,52 a	0,21 a	0,30 c
	59-84	493,31 a	44,98 d	461,70 d	1,35 a	0,42 d	0,51 a	0,19 b	0,31 bc
	84-138	497,63 a	54,56 b	447,80 d	1,40 a	0,28 e	0,54 a	0,22 a	0,32 ab
	138-200⁺	464,21 b	50,88 c	484,90 c	1,42 a	0,21 e	0,51 a	0,17 c	0,33 a
Spodosol (Valley)	0-25	18,12 a	16,98 a	964,89 a	1,45 c	4,37 a	0,48 a	0,39 a	0,08 a
	25-59	10,00 b	6,52 b	983,47 a	1,64 b	0,61 b	0,39 b	0,36 b	0,02 b
	59-120+	9,00 b	7,66 b	983,33 a	1,72 a	0,52 c	0,39 b	0,33 c	0,03 b

Soil attributes		Carbon (%)
Oxisol - Plateau
Clay content(g kg-¹)		- 0,87^* * and ns = no significant at 5% probability.
Soil bulk density (g cm^-3)		- 0,81^* * and ns = no significant at 5% probability.
Total porosity (m^-3m^-3)		0,82^* * and ns = no significant at 5% probability.
Macroporosity (m^-3m^-3)		0,60^* * and ns = no significant at 5% probability.
Microporosity (m^-3m^-3)		- 0,71^* * and ns = no significant at 5% probability.
Ultisol - Slope
Clay content (g kg^-1)		-0,81^* * and ns = no significant at 5% probability.
Soil bulk density (g cm^-3)		-0,80^* * and ns = no significant at 5% probability.
Total porosity (m^-3m^-3)		- 0,33^ns * and ns = no significant at 5% probability.
Macroporosity (m^-3m^-3)		0,10^ns * and ns = no significant at 5% probability.
Microporosity (m^-3m^-3)		- 0,60^* * and ns = no significant at 5% probability.
Spodosol - Valley
Clay content (g kg^-1)		0,45^ns * and ns = no significant at 5% probability.
Soil bulk density (g cm^-3)		- 0,80^* * and ns = no significant at 5% probability.
Total porosity (m^-3m^-3)		0,87^* * and ns = no significant at 5% probability.
Macroporosity (m^-3m^-3)		0,72^* * and ns = no significant at 5% probability.
Microporosity (m^-3m^-3)		0,61^* * and ns = no significant at 5% probability.

Depth (cm)	Carbon Stock
Depth (cm)	(Transect of 850 m)	Igarapé Açu Watershed (Area: 2.678,68 ha)
Oxisol - Plateau
0 - 40	90 Ac	100.210,8 Ac
0 - 100	136,5 Ab	151.838,4 Ab
0 - 200	175,5 Aa	195.236,7 Aa
Ultisol - Slope
0 - 40	84 Ac	80.470,8 Bc
0 - 100	116 Bb	111.477,1 Bb
0 - 200	159 Ba	152.611,9 Ba
Spodosol - Valley
0 - 25	160 Bb	96.902,3 Ab
0 - 120	241 Ca	146.018,0 Aa

Author	Soil types or localization	Carbon stock	Greatness unit	Depht
Batjes (1999)	Tropical soils	616 à 640	Gt C	Até 2 m
Batjes and Dijkshoorn (1999)	Oxisol	50,5	t ha^-1	0,0 - 0,3 m
Batjes and Dijkshoorn (1999)	Ultisol	44	t ha^-1	0,0 - 0,3 m
Batjes and Dijkshoorn (1999)	Amazonian soils	66	Pg C	No informed
(BERNOUX 1998BERNOUX, M.; ARROUAYS, D.; CERRI, C.C.; BOURENNANE, H. Modelling vertical distribution of carbon in Oxisols of the Western Brazilian Amazon (Rondônia). Soil Science, v.163, p.941-951, 1998.; BATJES, DIJKSHOORN, 1999)	Soils under forest	73 à 98	Mg ha^-1	0,0 -1,0 m
Bernoux et al. (2001)BERNOUX, M.; ARROUAYS, D.; CERRI, C.C.; BOURENNANE, H. Modelling vertical distribution of carbon in Oxisols of the Western Brazilian Amazon (Rondônia). Soil Science, v.163, p.941-951, 1998.	OxisolUltisolSpodosol	7,76 6,518,31	kgCm^-2	Up to 1,0 m
Bernoux et al. (2002)BERNOUX, M.; ARROUAYS, D.; CERRI, C.C.; BOURENNANE, H. Modelling vertical distribution of carbon in Oxisols of the Western Brazilian Amazon (Rondônia). Soil Science, v.163, p.941-951, 1998.	Northwest Mato Grosso	45	t ha^-1	0,0 - 0,3 m
(BOHN 1976; MORAES et al. 1995; BATJES, DIJKSHOORN 1999)	Acre, Legal Amazon, Amazonian region and South America(Oxisol and Ultisol)	6,3-5,9; 8,5-9,3; 10,2 e 12,0	kgm^-2	0,0 - 1,0 m
BUSO et al. (2007)	Oxisol and Ultisol	34,30 e 35,40	t ha^-1	0,0 - 0,3 m
(BOHN 1976; MORAES et al. 1995; BATJES, DIJKSHOORN 1999)	Acre, Legal Amazon, Amazonianregion and South America(Ultisol)	5,8-6,1; 9,5; 8,5 e 8,0	kgm^-2	0,0 - 1,0 m
Cerri et al. (2004)	Soils under forest/Rondônia	24 à 26	t ha^-1	0,0 - 0,2 m
Cerri et al. (2006)	Brazilian Amazon	3,5	Tg C ano^-1	0,0 - 0,3 m
Cerri et al. (2007)	Amazon soils	41-47	Pg C	Up to 1, 0 m
Clark (2000)	Soils under Tropical Forest/Costa Rica	120-200	MgCha^-1	Up to 1,0 m
Clark (2002)	Soils under Tropical Forest/Costa Rica/Inceptisol	191,1	MgCha^-1	Up to 1,0 m
Clark (2002)	Soils under Tropical Forest/Costa Rica e Ultisol (at plateau and slope)	224,2 e 184,6	MgCha^-1	Up to 1,0 m
Desjardins et al. (2004)DESJARDINS, T.; BARROS, E.; SARRAZIAN M.; GIARDINA, C.; MARIOTTI, A. Effects of forest conversion to pasture on soil carbon content and dynamics in Brazilian Amazon. Agriculture Ecosystems & Environment, v.103, n.2, p.365-373, 2004.	Soils near of Manaus e Marabá soils	5,5 à 6,1 e 2,9 à 3,4	kgm^-2	Up to 20 cm
Eswaran et al. (1993)	Tropical soils	506	Pg C	No informed
Fearnside (1997, 2000, 2003)	Legal Amazon	138	GtC	Até 8,0 m
Filho et al. (2006)	Mato Grosso	56,73 à 64,35	t ha^-1	0,0 - 0,6 m
IBGE (2012)INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA - IBGE. Maior estoque de carbono da região da Amazônia Legal está no solo. [acesso em: 27 jul. 2012] Disponível em: http://www.ibge.gov.br/home/. http://www.ibge.gov.br/home/... ,	Legal Amazon	55,7	tCha^-1	0,5 m
IBGE (2012)INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA - IBGE. Maior estoque de carbono da região da Amazônia Legal está no solo. [acesso em: 27 jul. 2012] Disponível em: http://www.ibge.gov.br/home/. http://www.ibge.gov.br/home/...	Legal Amazon	95,7	tCha^-1	1,0 m
Jobbagy and Jackson, (2000)	Tropical soils	474	Gt C	Up to 3,0 m
Jobbagy and Jackson (2000)	Tropical soils	1037	Gt C	Below 3,0 m
Moraes (1995)	Tropical soils	22	kgCm^-2	Up to 1,0 m
Moraes et al. (1996)	Soils under forest/ Southwest amazon basin	37	t ha^-1	0,0 - 0,3 m
Moraes et al. (1995)	Amazon basin soils	45 x 10⁶	Pg C	Até 1,0 m
Moraes et al. (1995)	Amazon basin soils	20 x 10⁶	Pg C	0,0 - 0,2 m
Melo (2003)	Acre soils	1	Pg C	0,0 - 1,0 m
Melo (2003)	Acre soils - Ultisol	3,5 à 3,6	kgm^-2	0,0 - 0,3 m
Melo (2003)	Acre soils - Oxisol	3,3 à 4,2	kgm^-2	0,0 - 0,3 m
Melo (2003)	Acre soils - Ultisol	5,8 à 6,8	kgm^-2	0,0 - 1,0 m
Melo (2003)	Acre soils - Oxisol	5,9 à 7,6	kgm^-2	0,0 - 1,0 m
Neil et al. (1997)	Rondônia - Nova Vida	32,3	t ha^-1	0,0 - 0,3 m
Neil et al. (1997)	Rondônia - Porto Velho	62	t ha^-1	0,0 - 0,3 m
Post et al. (1982)	Tropical soils	316	Gt C	Up to 1,0 m
Potter et al. (1998)POTTER, C.S.; DAVIDSON, E.A.; KLOOSTER S.A.; NEPSTAD, D.C.; NEGREIROS, G.H.; BROOKS, V. Regional application of an ecosystem production model for studies of biogeochemistry in Brazilian Amazonia. Global Change Biology, v.4, p.315-333, 1998.	Tropical soils - Amazonia	15,5	kgCm^-2	Up to 1,0 m
Potter et al. (1998)POTTER, C.S.; DAVIDSON, E.A.; KLOOSTER S.A.; NEPSTAD, D.C.; NEGREIROS, G.H.; BROOKS, V. Regional application of an ecosystem production model for studies of biogeochemistry in Brazilian Amazonia. Global Change Biology, v.4, p.315-333, 1998.	Tropical soils - Amazonia	106	Pg C	Up to 1,0 m
Potter et al. (1998)POTTER, C.S.; DAVIDSON, E.A.; KLOOSTER S.A.; NEPSTAD, D.C.; NEGREIROS, G.H.; BROOKS, V. Regional application of an ecosystem production model for studies of biogeochemistry in Brazilian Amazonia. Global Change Biology, v.4, p.315-333, 1998.	Tropical soils - Amazonia	74	Pg C	Up to 1,0 m
RADAMBRASIL (1981)	Tropical soils/Amazonia	30	kgCm^-2	Up to 1,0 m
Salimon (2007)SALIMON, C.I.; WADI, P.G.S.; MELO, A.W.F. Dinâmica do carbono na conversão de floresta para pastagens em argissolos da formação geológica solimões, no sudoeste da Amazônia. Revista de Biologia e Ciências da Terra, v.7, n.1, p.29-38, 2007.	Ultisol/Secundary forest with 11 years and 3 years; Southwest amazonian: Peixoto, respectively.	14 à 44 e10 à 38	Mg C ha^-1	0-60 cm
Salimon (2007)SALIMON, C.I.; WADI, P.G.S.; MELO, A.W.F. Dinâmica do carbono na conversão de floresta para pastagens em argissolos da formação geológica solimões, no sudoeste da Amazônia. Revista de Biologia e Ciências da Terra, v.7, n.1, p.29-38, 2007.	Ultisol/Secundary forest with 3 years; Southwest a mazonian: Humaitá	14 à 41	Mg C ha'¹	0-60 cm
Salimon (2007)SALIMON, C.I.; WADI, P.G.S.; MELO, A.W.F. Dinâmica do carbono na conversão de floresta para pastagens em argissolos da formação geológica solimões, no sudoeste da Amazônia. Revista de Biologia e Ciências da Terra, v.7, n.1, p.29-38, 2007.	Legal reserve/ Southwest amazonian: Peixoto e Humaitá, respectively	14 à 45 e 11 à 33	Mg C ha^-1	0-60 cm
Sommer et al. (2000)SOMMER, R.; DENICH, M.; VLEK, P.L.G. Carbon storage and root penetration in deep soils under small-farmer land-use systems in the Eastern Amazon region, Brazil. Plant and Soil, v.219, p.231-241, 2000.	Oxisol - Pará	143	Mg C ha^-1	Below 3,0 m
Trumbore et al. (1990)TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995.	Ultisol/Curuá-Una/Pará	54	t Cha-¹	60 cm
Trumbore et al. (1990)TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995.	Ultisol/Curuá-Una/Pará	76	t Cha^-1	60-150 cm
Trumbore et al. (1995)TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995.	Tropical soils	168	Mg C ha^-1	Below 3,0 m
Trumbore et al. (1995)TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995.	Paragominas soils/Pará	155	t Cha^-1	1,0 - 8,0 m
Trumbore et al. (1995)TRUMBORE, SE.; DAVIDSON, EA.; CAMARGO, P.B.; NEPSTAD, D.C.; MARTINELLI, L.A. Belowground cycling of carbon in forests and pastures of Eastern Amazônia. Global Biogeochemical Cycles, v.9, p.515-528, 1995.	Extrapolation to the Amazonian region	138 - 276	Gt Cha^-1	Até 8,0 m
Veldkamp et al. (2003)VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.	Tropical soils under Forest/Costa Rica	90-130	Mg C ha^-1	Above 1,0 m
Veldkamp et al. (2003)VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.	Tropical residual soils under Forest/Costa	330	Mg C ha^-1	Below 3m
Veldkamp et al. (2003)VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.	Tropical alluvial soils under Forest/Costa Rica	214	Mg C ha^-1	Below 3m
Veldkamp et al. (2003)VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.	Tropical residual soils under Pasture/Costa Rica	300	Mg C ha^-1	Below 3m
Veldkamp et al. (2003)VELDKAMP, E.; BECKER, A.; SCHWENDENMANN, L.; CLARK, D.A.; BISPING, H.S. Substantial labile carbon stocks and microbial activity in deeply weathered soils below a tropical wet forest. Global Change Biology, v.9, p.1171-1184, 2003.	Tropical alluvial soils under Pasture/Costa Rica	201	Mg C ha^-1	Below 3m

Brasil

Brasil

SOIL ORGANIC CARBON, CARBON STOCK AND THEIR RELATIONSHIPS TO PHYSICAL ATTRIBUTES UNDER FOREST SOILS IN CENTRAL AMAZONIA

CARBONO ORGÂNICO DO SOLO, ESTOQUE DE CARBONO E SUA RELAÇÃO COM ATRIBUTOS FÍSICOS SOB SOLOS FLORESTAIS NA AMAZÔNIA CENTRAL

ABSTRACT

RESUMO

1. INTRODUÇÃO

2. MATERIALS AND METHODS

3. RESULTS

4. DISCUSSION

5. CONCLUSIONS

6. ACKNOWLEDGEMENTS

7. REFERENCES

Publication Dates

History