Histosols in an Upper Montane Environment in the Itatiaia Plateau

Soares, Paula Fernanda Chaves; Anjos, Lúcia Helena Cunha dos; Pereira, Marcos Gervasio; Pessenda, Luiz Carlos Ruiz

doi:10.1590/18069657rbcs20160176

ABSTRACT:

Highland environments favor accumulation and preservation of soil organic matter (SOM) due to low temperatures, leading to the formation of Histosols. The Itatiaia National Park (INP), Rio de Janeiro, Brazil, offers conditions for preservation of SOM deposited over time, which has led to the formation of these soils. The objective of this study was to characterize Histosols in this environment, with the premise that it may provide evidence of changes in vegetation. Organossolos (Histosols) were sampled, characterized, described, and analyzed for their properties, stable isotopes of ¹²C and 13 14 15 14

C, N and N, and dating of organic matter through C. The soils were classified in the Brazilian Soil Classification System as Organossolo Háplico Hêmico típico - RJ-01 (Haplohemists) and Organossolo Fólico Sáprico cambissólico - RJ-02 (Udifolists). The morphological properties, degree of transformation, and chemical fractioning of SOM were consistent with hemic and sapric materials. The δ¹³C and δ¹⁵N isotopic analyses showed a difference in the contribution of plant materials. In RJ-01, there was previous influence of algae, due to poor drainage, and depletion of δ¹³C, suggesting a mix of C₃ and C₄ plants. RJ-02 showed influence of C₃ type plants. The ¹⁴C dating for RJ-01 was 3280±80 years, and for RJ-02, 2005±5 years (modern age).

Keywords:
peat lands; Itatiaia National Park; environmental changes

INTRODUCTION

Histosols in a tropical climate are formed at two different altitudinal zones. The first, which is more common, is at elevations lower than 30 m, called low altitude peat lands (lowland environment). The second, which are at elevations above 1,200 m, are called mountain peat lands (upper montane environment) (Chimner and Karberg, 2008Chimner RA, Karberg JM. Long-term carbon accumulation in two tropical mountain peatlands, Andes Mountains, Ecuador. Mires Peat. 2008;3:1-10. ISSN 1819-754X; Benavides and Vitt, 2014Benavides JC, Vitt DH. Response curves and the environmental limits for peat-forming species in the northern Andes. Plant Ecol. 2014;215:937-52. doi:10.1007/s11258-014-0346-7
https://doi.org/10.1007/s11258-014-0346-... ). Both of these are found in South America, Africa, and Papua New Guinea (Page et al., 2011Page SE, Rieley JO, Banks CJ. Global and regional importance of the tropical peatland carbon pool. Global Change Biol. 2011;17:798-818. doi:10.1111/j.1365-2486.2010.02279.x
https://doi.org/10.1111/j.1365-2486.2010... ).

The Itatiaia plateau is located in the Mantiqueira Ridge, exhibiting an unique lithology, with mountainous terrain and rocky escarpments ranging from 2,000 to 2,791 m elevation, with its highest altitude in the Agulhas Negras Peak (Barreto et al., 2013Barreto CG, Campos JB, Roberto DM, Schwarzstein NT, Alves GSG, Coelho W. Plano de manejo do Parque Nacional do Itatiaia. Encartes 1,2,3 e 4 - Análise da Unidade de Conservação. Brasília, DF: 2013 [acessado em: 03 mar. 2016]. Disponível em: Disponível em: http://www.icmbio.gov.br/ portal/biodiversidade/unidades-de-conservacao/biomas-brasileiros/mata-atlantica/unidades-deconservacao-mata-atlantica/2181-parna-de-itatiaia.html .
http://www.icmbio.gov.br/ portal/biodive... ). As a result of elevation, the weather is cold and wet, with endemic vegetation, characterizing the Histosol formations in the Itatiaia environment as upper montane (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ; Chimner and Karberg, 2008Chimner RA, Karberg JM. Long-term carbon accumulation in two tropical mountain peatlands, Andes Mountains, Ecuador. Mires Peat. 2008;3:1-10. ISSN 1819-754X).

In general, poorly developed soils are found in these environments, such as Neossolos Litólicos and Cambissolos, and rocky outcrops. However, Histosols can be formed (Simas et al., 2005Simas FNB, Schaefer CEGR, Fernandes EI, Chagas AC, Brandão PC. Chemistry, mineralogy and micropedology of highland soils on crystalline rocks of Serra da Mantiqueira, southeastern Brazil. Geoderma. 2005;125:187-201. doi:10.1016/j.geoderma.2004.07.013
https://doi.org/10.1016/j.geoderma.2004.... ; Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ; Chimner and Karberg, 2008Chimner RA, Karberg JM. Long-term carbon accumulation in two tropical mountain peatlands, Andes Mountains, Ecuador. Mires Peat. 2008;3:1-10. ISSN 1819-754X; Scheer et al., 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ) by favoring the contribution of organic matter in detriment to its transformation, thus leading to its accumulation (Silva et al., 2013Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
https://doi.org/10.1590/S0100-0683201300... ; Weissert and Disney, 2013Weissert LF, Disney M. Carbon storage in peatlands: A case study on Isle of Man. Geoderma . 2013;204:111-9. doi:10.1016/j.geoderma.2013.04.016
https://doi.org/10.1016/j.geoderma.2013.... ; Bispo et al., 2015Bispo DFA, Silva AC, Matosinhos CC, Silva MLN, Barbosa MS, Silva BPC, Barral UM. Characterization of headwaters peats of the Rio Araçuaí, Minas Gerais State, Brazil. Rev Bras Cienc Solo. 2015;39:475-89. doi:10.1590/01000683rbcs20140337
https://doi.org/10.1590/01000683rbcs2014... ). In addition, they form as a result of a decrease in decomposition rates at low temperatures, while a constant supply of organic matter is maintained (Benites et al., 2007; Silva et al., 2009; Weissert and Disney, 2013; Benavides and Vitt, 2014Benavides JC, Vitt DH. Response curves and the environmental limits for peat-forming species in the northern Andes. Plant Ecol. 2014;215:937-52. doi:10.1007/s11258-014-0346-7
https://doi.org/10.1007/s11258-014-0346-... ; Cooper et al., 2015Cooper DJ, Kaczynski K, Slayback D, Yager K. Growth and organic carbon production in peatlands dominated by Distichia muscoides, Bolivia, South America. Arctic Antarctic Alpine Res. 2015;47:505-10. doi:10.1657/AAAR0014-060
https://doi.org/10.1657/AAAR0014-060... ; Hribljan et al., 2016;).

These soils have great environmental/ecological importance, owing to their high carbon storage capacity, ability to recharge aquifers, use as a substrate for vegetation (including species that have adapted to this environment), and their capacity to buffer toxic elements (Weissert and Disney, 2013Weissert LF, Disney M. Carbon storage in peatlands: A case study on Isle of Man. Geoderma . 2013;204:111-9. doi:10.1016/j.geoderma.2013.04.016
https://doi.org/10.1016/j.geoderma.2013.... ; Cooper et al., 2015Cooper DJ, Kaczynski K, Slayback D, Yager K. Growth and organic carbon production in peatlands dominated by Distichia muscoides, Bolivia, South America. Arctic Antarctic Alpine Res. 2015;47:505-10. doi:10.1657/AAAR0014-060
https://doi.org/10.1657/AAAR0014-060... ).

Soil organic matter (SOM) can provide evidence to assess environmental changes (Benites et al, 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ; Cooper et al, 2015Cooper DJ, Kaczynski K, Slayback D, Yager K. Growth and organic carbon production in peatlands dominated by Distichia muscoides, Bolivia, South America. Arctic Antarctic Alpine Res. 2015;47:505-10. doi:10.1657/AAAR0014-060
https://doi.org/10.1657/AAAR0014-060... ). It is a record of the origin, identity, and characteristics of past vegetation (Pessenda et al., 2004Pessenda LCR, Ribeiro AS, Gouveia SEM, Aravena R, Boulet R, Bendassolli JA. Vegetation dynamics during the late Pleistocene in the Barreirinhas region, Maranhão State, northeastern Brazil, based on carbon isotopes in soil organic matter. Quatern Res. 2004;62:183-93. doi: 10.1016/j.yqres.2004.06.003
https://doi.org/10.1016/j.yqres.2004.06.... ), since plants take up C differently according to their photosynthetic cycle (C₃, C₄, and CAM). From the natural abundance of isotopes of C and N in the SOM, it is possible to make inferences regarding the originating plants by establishing natural succession models (Pessenda et al., 2004; Silva et al., 2013Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
https://doi.org/10.1590/S0100-0683201300... ). The interpretation of these analyses (¹²C, ¹³C, ¹⁴N, and ¹⁵N) reveals information about previous vegetation and, when temporally synchronized with ¹⁴C lifetimes, may indicate possible local environmental changes (Francisquini et al., 2014Francisquini MI, Lima CM, Pessenda LCR, Rossetti DF, França MC, Cohen MCL. Relation between carbon isotopes of plants and soils on Marajó Island, a large tropical island: Implications for interpretation of modern and past vegetation dynamics in the Amazon region. Palaeogeogr Palaeoclim Palaeoecol. 2014;415:91-104. doi:10.1016/j.palaeo.2014.03.032
https://doi.org/10.1016/j.palaeo.2014.03... ; França et al., 2015França MC, Alves ICC, Castro DF, Cohen MCL, Rossetti DF, Pessenda LCR, Lorente FL, Fontes NA, B Junior AA, Giannini PC, Francisquini MI. A multi-proxy evidence for the transition from estuarine mangroves to deltaic freshwater marshes, Southeastern Brazil, due to climatic and sea-level changes during the late Holocene. Catena. 2015;128:155-66. doi:10.1016/j.catena.2015.02.005
https://doi.org/10.1016/j.catena.2015.02... ).

The Itatiaia National Park (INP), Brazil's first national park, has great environmental importance as a conservation unit, which justifies studies on soil limitations and weaknesses. Moreover, Histosols in an upper montane environment have distinct geomorphic features (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ; Scheer et al., 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ) compared to those in floodplain and coastal plain environments.

It is assumed that SOM deposited over time in the upper montane environment of the INP has been preserved during the formation of Histosols, so that a study of these soils may reveal vegetation changes between previous and current environments. In this context, our study aimed to characterize Histosols in upper montane environments in the Itatiaia Plateau through morphological and physical descriptions, chemical properties, isotopic analyses of carbon and nitrogen, and dating by ¹⁴C.

MATERIALS AND METHODS

Characterization of the área

The area is located in the Serra da Mantiqueira within the Itatiaia National Park, Rio de Janeiro, in a full conservation unit spreaded over an area of 225.54 km². For management purposes, the park was divided into two zones based on altitude. This study was undertaken in the zone at the higher altitude range, which is characterized by mountainous and rugged terrain, with altitudes ranging from 2,000 to 2,791 m, culminating in the Agulhas Negras Peak (Barreto et al., 2013Barreto CG, Campos JB, Roberto DM, Schwarzstein NT, Alves GSG, Coelho W. Plano de manejo do Parque Nacional do Itatiaia. Encartes 1,2,3 e 4 - Análise da Unidade de Conservação. Brasília, DF: 2013 [acessado em: 03 mar. 2016]. Disponível em: Disponível em: http://www.icmbio.gov.br/ portal/biodiversidade/unidades-de-conservacao/biomas-brasileiros/mata-atlantica/unidades-deconservacao-mata-atlantica/2181-parna-de-itatiaia.html .
http://www.icmbio.gov.br/ portal/biodive... ). The geology in the upper part of the INP is represented by the Itatiaia Alkaline Massif rocks that are placed over the crystalline basement gneisses of the Serra da Mantiqueira. This formation is rare, and the alkaline massif reaches high altitudes. The following types of rocks can be found: gneisses, nepheline syenite, syenite quartz, alkaline granite, and magmatic breccias, in addition to colluvial and alluvial sediments (Barreto et al., 2013).

Climate in the region is classified as Cwa, which corresponds to a sub-tropical climate with hot and rainy summers and cold and dry winters, with average annual temperature of 16 °C and average annual rainfall of 2,300 mm (Köppen, 1948Köppen W. Climatologia: con un estudio de los climas de la tierra. México: Fondo de Cultura Econômica; 1948.). In the upper part, at the Agulhas Negras peak, frost occurs, and temperatures can reach -10 °C in the months from June to August (Barreto et al., 2013Barreto CG, Campos JB, Roberto DM, Schwarzstein NT, Alves GSG, Coelho W. Plano de manejo do Parque Nacional do Itatiaia. Encartes 1,2,3 e 4 - Análise da Unidade de Conservação. Brasília, DF: 2013 [acessado em: 03 mar. 2016]. Disponível em: Disponível em: http://www.icmbio.gov.br/ portal/biodiversidade/unidades-de-conservacao/biomas-brasileiros/mata-atlantica/unidades-deconservacao-mata-atlantica/2181-parna-de-itatiaia.html .
http://www.icmbio.gov.br/ portal/biodive... ). Vegetation in the plateau is described as a high altitude rocky outcrop complex (Benites et al. 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ), formed by a mosaic of vegetation types associated with the Atlantic Forest. Vegetation in the study site consists of herbaceous graminoid plants, with a predominance of Cyperaceae and Poaceae, arranged in clumps, and fewer incidences of other species.

Soil sampling and analyses

The two profiles were collected at different locations in the landscape (Figure 1), covering an altitudinal range of 300 m and at a horizontal distance of about 3 km from each other; measurements were made with a GPS unit (Garmin GPSMAP 78). The RJ-01 profile was collected at 23 K 0533769 7524084 (WGS 84) at an altitude of 2,100 m in a depression zone at the bottom of closed valley, where the water table was high (hydromorphic environment with poor drainage). The RJ-02 profile was collected from the lower third of the slope in a moderately drained area located at 23 K 0530905 7525596 (WGS 84) at an altitude of 2,400 m. The profile descriptions, both general and morphological, were registered according to Santos et al. (2005Santos RD, Lemos RC, Santos HG, Ker JC, Anjos LHC. Manual de descrição e coleta de solo no campo. 5a ed. Viçosa, MG: Sociedade Brasileira de Ciência do Solo; 2005.), and the soil was identified according to the Brazilian System of Soil Classification - SiBCS (Santos et al., 2013).

Characterization of organic material was carried out according to the methods recommended for Organossolos (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.). The following aspects were analyzed: von Post humification scale, unrubbed fiber content (URF), rubbed fiber content (RF), pyrophosphate solubility index (PFI), organic matter (OM) and mineral material (MM) contents, minimum residue (MR), and the organic matter density (OMD). Physical and chemical properties were analyzed according to Silva (2009Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.), and chemical fractionation of humic substances was carried out according to the method recommended by the International Humic Substances Society, with modifications suggested by Benites et al. (2003Benites VM, Madari B, Machado PLOA. Extração e fracionamento quantitativo de substâncias húmicas do solo: um procedimento simplificado de baixo custo. Rio de Janeiro: Embrapa Solos; 2003.). Total C, H, and N were measured using the dry combustion method in the CHN elemental analyzer (TrueSpec Series: Carbon, Hydrogen, Nitrogen Elemental, Macro).

Figure 1
Profile locations within the landscape of Itatiaia National Park (INP), Rio de Janeiro, Brazil (RJ-01: 23 K 0533769 7524084 (WGS 84), elevation: 2100 m, and RJ-02: 23 K 0530905 7525596 (WGS 84), elevation: 2400 m).

Soil samples were collected in trenches for isotopic analyses, from bottom to top in order to avoid contamination, at the following depths: 0.00-0.10, 0.10-0.20, 0.20-0.30, 0.30-0.40, 0.40-0.50, 0.50-0.60, 0.60-0.70, 0.70-0.80, 0.80-0.90, 0.90-1.00 m. An auger was used for collecting samples at the following depths: 1.00-1.10, 1.10-1.20, 1.20-1.30, 1.30-1.40, 1.40-1.50, 1.50-1.60, 1.60-1.70, 1.70-1.80, 1.80-1.90, and 1.90-2.00 m. Samples were ground, passed through a 100 mesh sieve, and then sent to the Stable Isotope Laboratory, in the Center for Nuclear Energy in Agriculture (Centro de Energia Nuclear na Agricultura - CENA) for determination of ¹²C, ¹³C, ¹⁴N, and ¹⁵N values. This was carried out in a Finnigan Delta Plus mass spectrometer coupled to a total C and N auto-analyzer, Carlo Erba AE1108 - Finnigan MAT, Bremen, having PDB as a standard for carbon and atmospheric air for nitrogen. All isotope collections were carefully conducted without contact with hands or other objects that could contaminate the samples with external carbon.

Soil samples were collected from a depth of 0.40-0.50 m for ¹⁴C dating in the SOM. In order to obtain the humin fraction, roots and soil fauna were first manually cleared, following Gouveia et al. (1999Gouveia SEM, Pessenda LCR, Aravena R. Datação da fração humina da matéria orgânica do solo e sua comparação com idades 14C de carvões fósseis. Quím Nova. 1999:22:810-4. doi:10.1590/S0100-40421999000600007
https://doi.org/10.1590/S0100-4042199900... ). This was followed by removal of recent SOM, humic acid (HA), and fulvic acid (FA) fractions. This procedure is justified since, according to the author, dating all SOM fractions would underestimate the result. The HA and FA fractions are younger, and due to their higher solubility, they migrate from the surface, which has current residual input, to the subsurface, thereby masking the age of the original SOM that generated the Organossolos.

The humin fraction was sent to Stable Isotope Laboratory - CENA, where, for benzene synthesis, 70 g of humin was added to a tube containing copper oxide and lead chromate and heated at 650 °C for 60 min to form CO₂. This was collected and cooled with liquid nitrogen (-180 °C) and brought into contact with metallic lithium at 600 to 700 °C to form lithium carbide. At the end of the reaction, distilled water was added, causing hydrolysis and production of acetylene. Benzene was obtained by trimerization of acetylene in a catalytic converter at 90 °C for 2 h. Then, 0.5 mL of a scintillation solution (43.5 g of PPO and 2.59 g POPOP per liter of toluene) was added to the synthesized benzene, and the solution was kept in an unlit environment for 4 h for elimination of the phosphorescence effect. The solution was counted in a liquid scintillation spectrometer, Packard Tri-Carb 1550, with a low level of background radiation, for a period of 3000 min, at 100 min intervals.

Data were then evaluated using specific mathematical procedures, and conventional 14 C lifetime was corrected for isotopic fractionation.

RESULTS AND DISCUSSION

Morphological properties and SOM characterization (SiBCS)

The RJ-01 and RJ-02 profiles presented histic diagnostic horizons (H and O) of 0.57 m and 0.59 m combined thicknesses, respectively (Table 1). These horizons are superimposed on mineral horizons, with an H-Cg sequence in RJ-01 and O-Bi in RJ-02. Identification of the Cg horizon in the RJ-01 profile is consistent with the high water table, conditioned by its position at the bottom of the valley, with drainage being influenced by bedrock outcrops and steep slopes (Benites et al., 2007Benites VM, Schaefer CEGR, Simas FNB, Santos HG. Soils associated with rock outcrops in the Brazilian mountain ranges Mantiqueira and Espinhaço. Rev Bras Bot. 2007;30:569-77. doi:10.1590/S0100-84042007000400003
https://doi.org/10.1590/S0100-8404200700... ; Scheer et al., 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ; Cipriano-Silva et al., 2014Cipriano-Silva RC, Valladares GS, Pereira MG, Anjos LHC. Caracterização de Organossolos em ambientes de várzea do Nordeste do Brasil. Rev Bras Cienc Solo . 2014;38:26-38. doi:10.1590/S0100-06832014000100003
https://doi.org/10.1590/S0100-0683201400... ). The color of the histic horizons (H and O) was uniform, which was 10YR3/2 in all horizons in RJ-01, and N2/ in most of the RJ-02 profile, thus ranging from very dark grayish brown to black (Table 1). In the RJ-02 profile, the Bi and Bi₂/BC horizons exhibited a lighter matrix color (N4/). The colors seen in the histic horizons satisfy the concept of the Organossolo (Histosol) class in the SiBCS (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.).

The long-term use of agricultural peats leads to changes in soil physical and chemical properties, particularly in layers that are not normally saturated with water, regardless of the initial vegetation composition (Könönen et al., 2015Könönen M, Jauhiainen J, Laiho R, Kusin RK, Vasander H. Physical and chemical properties of tropical peat under stabilised land uses. Mires Peat . 2015;16:1-13.). Since the INP is a protected area, anthropogenic pressure consists of leisure activities along the park trails, and access to other areas is limited. Therefore, differences in morphological properties are more closely related to drainage, which in RJ-02 leads to greater variation in wetting and drying, due to the higher topographic position and absence of hydromorphism. Both the RJ-01 and RJ-02 profiles have material of an organic nature characterizing histic horizons. However, distinctions in the degree of decomposition of organic material are noticeable, since RJ-01 has higher amounts of fiber throughout the profile. The structure of the H and O horizons is granular, varying in size, in which RJ-02 has small and medium aggregates (Table 1). In RJ-02, sub-angular block structures, and even angular ones, were observed in the subsurface horizon (Bi), indicating a greater degree of structural development compared to RJ-01, which has massive structure in the Cg horizons.

The morphological properties and their location in the landscape indicate that the organic horizons (H) in the RJ-01 profile were formed by the paludization process (H₁, H₂, and H₃) and are followed by two horizons with evidence of gleization (Cg₁ and Cg₂). In RJ-02, organic horizons (O) are formed by the accumulation of organic matter (O₁, O₂, and O₃) favored by the low temperature, which reduces their transformation even under good drainage conditions, and the subsequent two horizons of a mineral nature have characteristics, such as variation in the block structure, which identify the subsurface horizon as B incipient (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.).

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Table 1
Description of morphological properties and degree of decomposition of organic matter indicators in Organossolos in the upper montane environment of Itatiaia National Park, Rio de Janeiro, Brazil

The SOM transformation indicators in the histic horizons show different degrees of decomposition for profiles RJ-01 and RJ-02 (Table 1). According to the von Post scale, RJ-01 was reported as Hemic in the third taxonomic level due to the dominance of this degree of decomposition through most of the first meter of soil. In contrast, RJ-02 had a comparatively greater degree of transformation of organic matter throughout the profile, which identified it as Sapric. The values for the rubbed fibers index and the sodium pyrophosphate index (Table 1) complement the interpretation of the von Post scale in classification as Organossolos (Histosols) in the SiBCS. Better drainage in the RJ-02 profile favored mineralization and/or humidification by lowering fiber content, which explains the dominance of more processed materials (Sapric).

The two profiles are under similar climate and vegetation conditions at present, but show morphological differences in horizon sequences and in the degree of transformation of organic matter, as well as in the influence of topographical features. The hydromorphic environment, the presence of large amounts of fiber, and the degree of transformation in SOM in the histic horizon led to classification of the RJ-01 profile as Organossolo Háplico Hêmico típico (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.), corresponding to Haplohemists in Soil Taxonomy (Soil Survey Staff, 2014). In contrast, the RJ-02 profile, with better drainage and an incipient subsurface horizon environment was classified as Organossolo Fólico Sáprico cambissólico in the SiBCS (Santos et al., 2013), corresponding to Udifolists in Soil Taxonomy (Soil Survey Staff, 2014).

Chemical and physical properties

The exchangeable complex of Histosols has characteristics different from other so-called mineral soils that act as vegetation regulators, causing the occurrence of a few species and promoting some species to emerge as dominants (Benavides and Vitt, 2014Benavides JC, Vitt DH. Response curves and the environmental limits for peat-forming species in the northern Andes. Plant Ecol. 2014;215:937-52. doi:10.1007/s11258-014-0346-7
https://doi.org/10.1007/s11258-014-0346-... ). The pH values ranged from 4.4 to 5.4, indicating medium acidity (Table 2). This is higher than values reported in other studies, such as 2.8 to 4.7 in the upper montane Organossolos Háplicos in Serra de Espinhaço, MG, Brazil (Silva et al., 2013Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
https://doi.org/10.1590/S0100-0683201300... ) and 2.9 to 3.2 in Serra da Igreja, PR, Brazil (Scheer et al, 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ) and 2.7 to 3.8 for Histosols in Indonesia (Könönen et al., 2015Könönen M, Jauhiainen J, Laiho R, Kusin RK, Vasander H. Physical and chemical properties of tropical peat under stabilised land uses. Mires Peat . 2015;16:1-13.). The higher pH values observed in the soils of the upper part of the INP could be a result of the alkaline parent material.

In general, the levels of exchangeable elements (Table 2) were low, with the exception of Al³⁺ and H⁺, which are common in Histosols. Aluminum values were high in RJ-01 (ranging from 1.5 cmol_c kg^-1 in the Cg₁ horizon to 6.0 cmol_c kg^-1 in H₁). However, in RJ-02 they ranged from 1.3 cmol_c kg^-1 in Bw₂/BC to 1.7 cmol_c kg^-1 in O₁. Hidrogen prevailed in the sorption complex of all profiles. However, the RJ-02 profile stood out as the lowest amplitude, 5.5 cmol_c kg^-1 in the Bw₂/BC horizon, up to 11.5 cmol_c kg^-1 in the O₁ horizon. Due to the ability of SOM to complex Al, thereby reducing its toxicity in the soil solution, higher Al levels usually represent no limitation to plants in organic soils. In contrast, increased levels of hydrogen result from decomposition of plant residues wherein organic acids are released into the soil (Silva et al., 2009Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.). The values of H⁺ in the RJ-01 profile are related to hydromorphism, which leads to slow decomposition of plant material and permanence of acids that are distributed throughout the profile (Silva, 2009; Scheer et al., 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ).

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Table 2
Chemical properties of Organossolos in the upper montane environment of Itatiaia National Park, Rio de Janeiro, Brazil

The values of Ca, Mg, Na, K, and P were very low in both profiles, similar to Könönen et al. (2015Könönen M, Jauhiainen J, Laiho R, Kusin RK, Vasander H. Physical and chemical properties of tropical peat under stabilised land uses. Mires Peat . 2015;16:1-13.) study, which found low values of nutrients other than P in Histosol without human intervention. In our study, Mg stood out as higher than Ca in all horizons, which could be due to the contribution of related rocks (nepheline-syenite). As a result of the low availability of nutrients, the sum of bases (S) ranged from 1.46 to 2.64 cmol_c kg^-1, and the cation exchange capacity (T value) from 8.36 to 32.93 cmol_c kg^-1. The very low base saturation (V) shows the influence of high values of H⁺ in the SOM.

The physical properties used in Organossolos characterization and classification (Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.) are different from those used for soils with a predominance of mineral material. These properties are gravimetric moisture (% M), soil bulk density (Bd), particle density (Pd), organic matter density (OMD), minimum residue (MR), mineral material (MM), and total pore volume (TPV). They are related to organic carbon (OC) content, usually in a directly proportional manner. The values of these properties in the RJ-01 and RJ-02 profiles were similar (Table 3) and the organic matter content influenced all the physical variables.

The gravimetric moisture percentage was directly related to soil organic matter values, which is expected, given that it has large hygroscopicity (ability to capture and store water from the atmosphere). This is also a property commonly observed in Histosols, i.e., the large amount of water retained in organic horizons. The % M values decreased as depth increased, and in RJ-02, mineral horizons (Bw₁ and Bw₂/BC) had the lowest values of % M. In contrast, MM values increased with depth and were inversely proportional to the organic matter content, with the highest value (98.22 %) in RJ-02 at Bw₁. This pattern was also observed by D'Amore and Lynn (2002D'Amore DV, Lynn WC. Classification of forested Histosols in Southeast Alaska. Soil Sci Soc Am J. 2002;66:554-62. doi:10.2136/sssaj2002.0554
https://doi.org/10.2136/sssaj2002.0554... ) and Silva et al. (2009Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.).

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Profile Horizon Bd Pd OMD MR Gm MM TPV SOM ------------------- Mg m-3 ------------------- m m-1 ------------------------------ % ------------------------------ Organossolo Háplico Hêmico típico (Haplohemists) RJ-01 H1 0.60 1.56 0.23 0.25 18.48 61.14 61.14 38.86 H2 0.70 1.60 0.26 0.30 28.04 63.51 56.13 36.49 H3 0.70 1.72 0.19 0.34 14.42 73.00 59.63 27.00 Cg1 0.74 2.00 0.13 0.41 11.98 82.42 63.10 17.58 Cg2 0.82 1.92 0.18 0.43 12.61 78.27 57.15 21.73 Organossolo Fólico Sáprico cambissólico (Udifolists) RJ-02 O1 0.54 1.55 0.24 0.20 45.14 55.73 65.30 44.27 O2 0.54 1.69 0.23 0.21 40.45 58.01 68.02 41.99 )3 0.81 1.89 0.15 0.44 21.65 81.75 56.96 18.25 Bw1 0.95 1.98 0.10 0.56 8.93 89.22 52.13 10.78 Bw2/BC 1.17 2.15 0.41 0.50 10.13 64.65 45.69 35.35

Both profiles showed similar TPV, with values decreasing with depth and directly related to organic matter content, ranging from 68 to 46 %. The higher values at the surface are due to recent addition of organic material, which has greater number of macropores; in the process of decomposition (or mineralization), these pores collapse, decreasing their size and affecting total porosity. TPV values were higher than those found by Scheer et al. (2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ), who reported values from 10 to 33 % in upper montane Histosols at Serra da Igreja, Parana. However, the values were much smaller than those found by Könönen et al. (2015Könönen M, Jauhiainen J, Laiho R, Kusin RK, Vasander H. Physical and chemical properties of tropical peat under stabilised land uses. Mires Peat . 2015;16:1-13.) in Indonesian Histosols.

In both profiles, Bd values increased with depth and were inversely proportional to SOM content. The highest Bd value occurred in RJ-02 in Bw₂/BC (1.17 Mg m^-3), which is strongly influenced by the mineral fraction. Bd is a key physical property in Histosols, used in calculating OMD and as an indicator of the extent to which the organic matter is transformed (Lynn et al., 1947). Values are according to Silva et al. (2009Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.), who observed variation from 0.03 to 0.44 Mg m^-3 in Histosols from Serra do Espinhaço, MG. Overall, the two profiles studied in Itatiaia showed decreasing OMD with depth. This is a direct reflection of a higher degree of humification and mineralization of organic matter, which in highland environments shows a distinct pattern with soil depth.

The MR values range from 0.20 to 0.56 m m^-1, indicating the susceptibility of Histosols to degradation by the subsidence process (loss of volume). The MR is used to evaluate the maximum subsidence potential in horizons/layers formed of organic material, and are referred to as the thickness of the unit remaining after maximum subsidence (Lynn et al., 1974Lynn WC, MC Kinzie WE, Grossman RB. Field laboratory tests for characterization of Histosols. In: Aandahl AR, Buol SW, Hill DE, Bailey HH, editors. Histosols their characteristics, classification, and use. Madison: SSSA; 1974. p.11-20.).

Distribution of C, N, and carbon fractions in humic substances

Carbon values obtained by the CHN method were similar in their distribution across the soil depth in both profiles (Table 4). Moreover, in the surface horizons (H₁-RJ-01, and O₁-RJ-02) there is virtually no difference in C values (16.7 and 17.0 %). In these surface horizons, the cold weather and the upper montane environment have a similar influence on the type of vegetation (organism as the main soil formation factor). In the subsurface layers of the RJ-01 profile (with hydromorphism), an increase was observed in C values compared to the RJ-02 profile. Although these carbon values were low (Scheer et al., 2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... , 2013; Könönen et al., 2015Könönen M, Jauhiainen J, Laiho R, Kusin RK, Vasander H. Physical and chemical properties of tropical peat under stabilised land uses. Mires Peat . 2015;16:1-13.), according to Weissert and Disney (2013Weissert LF, Disney M. Carbon storage in peatlands: A case study on Isle of Man. Geoderma . 2013;204:111-9. doi:10.1016/j.geoderma.2013.04.016
https://doi.org/10.1016/j.geoderma.2013.... ), these values are within the average found in peat soils, ranging from 8.4 to 47.3 %.

The N and H values followed the behavior for C, as they are both related to SOM. The amounts of C, N, and H determined by the dry combustion method were higher in surface horizons and decreased with depth. A similar distribution was reported in a study by Scheer et al. (2011Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
https://doi.org/10.1590/S0100-0683201100... ) in a Serra do Mar (PR) upper montane environment.

The C/N ratio enables us to infer the dynamics of organic matter and its state of humification, and in Histosols, values are generally high (Broder et al., 2012Broder T, Blodau C, Biester H, Knorr KH. Peat decomposition records in three pristine ombrotrophic bogs in southern Patagonia. Biogeosciences. 2012.9:1479-91. doi:10.5194/bg-9-1479-2012
https://doi.org/10.5194/bg-9-1479-2012... ). In RJ-02, values for the C/N ratio were high in the horizons of mineral formation (Bw₁ and Bw₂/BC) and higher than those of organic horizons in the same profile. This result suggests higher SOM processing and, thus, interaction of organic and mineral material, contributing to greater stability of SOM. The C values in the chemical fractionation of SOM (Table 4) show high C content in the Humin fraction (C-HUM) in the surface horizons. This decreases with depth for both profiles, ranging from 165.24 g kg^-1 in H₁ to 27.12 g kg^-1 in Cg₂ in RJ-01, and from 159.43 g kg^-1 in O₁ to 15.71 in Bw₂/BC in RJ-02. In all horizons, the C-HUM values were higher than those of other fractions. In general, C-HUM values are higher, as C-HUM includes C from remnants of leaves and stems, and even charcoal. The C-HUM values were higher in the RJ-01 profile, identified as Hemic. This confirms classification as Organossolos (Histosols), which was based on analysis of the property of scrubbed fibers and the von Post scale that highlights the difference in the degree of SOM humification.

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Table 4
Carbon (C), hydrogen (H) and nitrogen (N) values, C/N ratio, C levels in the humic substances, and ratio of alkaline extract C-HAF/C-FAF in an upper montane environment in Organossolos of the Itatiaia National Park, RJ, Brazil

A contrast was observed in carbon in the humic acid fraction (C-HAF), the values showed an increasing and erratic distribution with depth (Table 4), with RJ-01 ranging from 4.54 for H1 to 5.93 g kg^-1 for H₃, and RJ-02 with lower values, ranging from 1.47 for Bw1 to 3.59 g kg^-1 for O₂). RJ-01 had higher values of carbon in the humic acid (C-HAF) and fulvic acid (C-FAF) fractions in relation to RJ-02. As the former profile was from an area with a high water table, the removal of labile organic fractions from the soil section is prevented, leading to the accumulation of soluble fractions of organic matter throughout the length of the profile. Smaller amounts of C-FAF in RJ-02 suggest that SOM is still in an evolutionary stage, in the process of forming more stable structures. For the C-HAF/C-FAF ratio, there was variation from 0.71 to 1.05 in RJ-01, and 1.04 to 1.36 in RJ-02 (Table 4). These values reflect the degree of polymerization of the organic matter; the higher this value, the more condensed the organic matter will be. Thus, the ratio confirms the von Post levels, the fiber percentage, and the C-HUM content, which indicate a lower level of SOM evolution in RJ-01.

Isotopic composition of carbon and nitrogen, and dating of humin via ¹⁴C

The %C and %N values were similar between the profiles, as already mentioned, decreasing with depth (Figure 2). As soils are under the same type of vegetation and upper montane environment, such formative factors (climate and organisms) act with the same intensity as in current pedogenesis and, therefore, topography is a major factor in profile differentiation. C contents up to a depth of 0.20 m were equal for both profiles (Table 4), varying markedly at 0.30 m and with depth, with RJ-02 showing lower levels of C up to 1.80 m. This greater preservation of C in RJ-01 results from its poor drainage, favoring SOM accumulation and maintenance. N showed a similar response, while the C:N ratio varied widely in RJ-02, with values from 13 to 28, showing irregular distribution in the profile (Figure 2).

Histosols have an average C:N ratio of about 26, indicating balance between mineralization and immobilization processes (Cools et al., 2014Cools N, Vesterdal L, De Vos B, Vanguelova E, Hansen K. Tree species is the major factor explaining C:N ratios in European forest soils. For Ecol Manage. 2014;311:3-16. doi:10.1016/j.foreco.2013.06.047
https://doi.org/10.1016/j.foreco.2013.06... ). These values vary according to vegetation and edaphic and climatic conditions. The highest degree of transformation was observed in RJ-02, with C:N values of around 25 at various depths in the profile (0.60, 1.0, 1.3, 1.7, and 1.9 m). As this profile is characterized by better drainage, the organic material supplied tends to decompose faster, due to greater efficiency of aerobic microorganisms in the SOM decomposition process. During the evolution of SOM, the values of C tend to stabilize, while those of N decrease. This is caused by the removal of N-rich groups such as amines, which increases the C:N ratio and results in a greater degree of humification (Silva et al., 2013Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
https://doi.org/10.1590/S0100-0683201300... .). For Histosols, this relationship is an indication of the degree of pedogenesis, due to the intense transformation of organic material that originates this soil.

The δ¹³C values indicated a relative ¹³C depletion over time (Figure 2), particularly in RJ-02, with values ranging from -28 at present (0.00-0.10 m depth, surface horizon with recent supply of vegetation material) to -22 in the past (1.90-2.00 m depth, in the profile basis). According to this variation (a 6 δ shift), the vegetation in the profiles consisted of a mix of C₃ and C₄ plants, which shared the same environment for some time. Values close to -21 indicate a mix of vegetation types (Pessenda et al., 2004Pessenda LCR, Ribeiro AS, Gouveia SEM, Aravena R, Boulet R, Bendassolli JA. Vegetation dynamics during the late Pleistocene in the Barreirinhas region, Maranhão State, northeastern Brazil, based on carbon isotopes in soil organic matter. Quatern Res. 2004;62:183-93. doi: 10.1016/j.yqres.2004.06.003
https://doi.org/10.1016/j.yqres.2004.06.... ). Therefore, over the course of time, the proportion of C₃ plants increased, leading to values of -28. The δ¹⁵N values ranged from 3 to 10, indicating changes in the local water system for both profiles. This was more pronounced for RJ-01, which exhibited a higher amplitude (Figure 2). Higher values indicate the preponderance of algal contribution to SOM (Peterson and Howarth, 1987Peterson BJ, Howarth RW. Sulfur, carbon, and nitrogen isotopes used to trace organic matter flow in the salt-marsh estuaries of Sapelo Island, Georgia. Limnol Oceanogr. 1987;32:1195-213. doi:10.4319/lo.1987.32.6.1195
https://doi.org/10.4319/lo.1987.32.6.119... ), as seen at a depth of 0.30 to 0.50 m, which is possibly the average annual water table height in the RJ-01 profile.

Assessing the relationship between δ¹³C and δ¹⁵N, the values that fall within a range of 10 to 8 for δ¹⁵N and from -20 to -25 for δ¹³C (purple circle in Figure 3), correspond to organic matter from algae, indicating a water saturated environment over long periods (Peterson and Howarth, 1987Peterson BJ, Howarth RW. Sulfur, carbon, and nitrogen isotopes used to trace organic matter flow in the salt-marsh estuaries of Sapelo Island, Georgia. Limnol Oceanogr. 1987;32:1195-213. doi:10.4319/lo.1987.32.6.1195
https://doi.org/10.4319/lo.1987.32.6.119... ). As for the ratio between δ¹³C and C:N, two clusters can be seen (purple circle in Figure 3), where RJ-01 has greater proximity to organic material from algae, and the material supplied in RJ-02 shows a pattern similar to that originating from C₃ plants (Peterson and Howarth, 1987). Thus, isotopic analysis of δ¹³C and δ¹⁵N allows the profiles to be differentiated according to the organic materials that contributed to the SOM, with earlier influence of algae in the RJ-01 profile depicting the hydrological regime (continuous presence of water), and of plants with a C₃ photosynthetic cycle in RJ-02.

Figure 2
Distribution of carbon and nitrogen content, C:N ratio, δ¹³C and δ¹⁵N, for Organossolos in the upper montane environment of Itatiaia National Park, Rio de Janeiro, Brazil, with increasing depth.

Figure 3
Relationships between δ¹³C and δ¹⁵N (left) and between δ¹³C and C:N (right) for Organossolos in the upper montane environment of Itatiaia National Park, Rio de Janeiro, Brazil.

Dating of the humin fraction in SOM through ¹⁴C showed different ages between the profiles. In RJ-01, the organic material was dated from 3,351 to 3,699 years (years before the present), while in RJ-02, was from 2,001 to 2,009 years (years before the present). This large difference in age between the two profiles sampled from areas located in proximity to each other highlights the influence of landscape in the maintenance of carbon supplied to form the Organossolos. In the RJ-01 profile, the landscape position and slope resulted in poor drainage conditions, while for the RJ-02 profile, they influenced the rate of decomposition through better drainage.

CONCLUSIONS

Based on isotopic analysis, different plant groups (C₃, C₄) colonized the environment and contributed to the formation of the Organossolos.

The influence of algae in the past, along with the presence of C₃ and C₄ plants, is noted on RJ-01, which has SOM dated at 3,280±80 years. The RJ-02 profile has more recent soil organic matter (2,005±5 years), with a higher degree of humification, and a greater quantity of C₃ plants contributing to the soil organic matter.

The upper montane environment and the local topographic conditions determined differentiation of the soils and influenced pedogenesis. They had a direct effect through climate and drainage conditions, and an indirect effect on the decomposition of soil organic matter.

ACKNOWLEDGMENTS

We thank IBAMA, ICMBIO, and the Itatiaia National Park staff for providing help for development of this study, allowing entry, providing accommodations, and permitting removal of material for analysis, according to the SISBIO authorization (Permit No. 31916/2012).

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» https://doi.org/10.4319/lo.1987.32.6.1195
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Santos RD, Lemos RC, Santos HG, Ker JC, Anjos LHC. Manual de descrição e coleta de solo no campo. 5a ed. Viçosa, MG: Sociedade Brasileira de Ciência do Solo; 2005.
Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
» https://doi.org/10.1590/S0100-06832011000400005
Scheer MB, Curcio GR, Roderjan CV. The Late Holocene upper montane cloud forest and high altitude grassland mosaic in the Serra da Igreja, Southern Brazil. An Acad Bras Cienc. 2013;85:769-83.
Silva AC, Horák I, Cortizas AM, Vidal-Torrado P, Racedo JR, Grazziotti PH, Silva EB, Ferreira CA. Turfeiras da Serra do Espinhaço Meridional-MG: I - Caracterização e classificação. Rev Bras Cienc Solo . 2009;33:1385-98. doi:10.1590/S0100-06832009000500030
» https://doi.org/10.1590/S0100-06832009000500030
Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.
Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
» https://doi.org/10.1590/S0100-06832013000500004
Simas FNB, Schaefer CEGR, Fernandes EI, Chagas AC, Brandão PC. Chemistry, mineralogy and micropedology of highland soils on crystalline rocks of Serra da Mantiqueira, southeastern Brazil. Geoderma. 2005;125:187-201. doi:10.1016/j.geoderma.2004.07.013
» https://doi.org/10.1016/j.geoderma.2004.07.013
Soil Survey Staff. Keys to soil taxonomy. 12th ed. Washington, DC: United States Department of Agriculture, Natural Resources Conservation Service; 2014.
Weissert LF, Disney M. Carbon storage in peatlands: A case study on Isle of Man. Geoderma . 2013;204:111-9. doi:10.1016/j.geoderma.2013.04.016
» https://doi.org/10.1016/j.geoderma.2013.04.016

How to cite:

Soares PFC, Anjos LHC, Pereira MG, Pessenda LCR. Histosols in an Upper Montane Environment in the Itatiaia Plateau. Rev Bras Cienc Solo. 2016;40:e0160176

Publication Dates

Publication in this collection
2016

History

Received
31 Mar 2016
Accepted
04 Apr 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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» http://www.icmbio.gov.br/ portal/biodiversidade/unidades-de-conservacao/biomas-brasileiros/mata-atlantica/unidades-deconservacao-mata-atlantica/2181-parna-de-itatiaia.html

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[20] Pessenda LCR, Ribeiro AS, Gouveia SEM, Aravena R, Boulet R, Bendassolli JA. Vegetation dynamics during the late Pleistocene in the Barreirinhas region, Maranhão State, northeastern Brazil, based on carbon isotopes in soil organic matter. Quatern Res. 2004;62:183-93. doi: 10.1016/j.yqres.2004.06.003
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[22] Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JA, Cunha TJF, Oliveira JB, editores. Sistema brasileiro de classificação de solos. 3a ed. Brasília, DF: Embrapa; 2013.

[23] Santos RD, Lemos RC, Santos HG, Ker JC, Anjos LHC. Manual de descrição e coleta de solo no campo. 5a ed. Viçosa, MG: Sociedade Brasileira de Ciência do Solo; 2005.

[24] Scheer MB, Curcio GR, Roderjan CV. Environmental functionalities of upper montane soils in Serra da Igreja, Southern Brazil. Rev Bras Cienc Solo . 2011;35:1113-26. doi:10.1590/S0100-06832011000400005
» https://doi.org/10.1590/S0100-06832011000400005

[25] Scheer MB, Curcio GR, Roderjan CV. The Late Holocene upper montane cloud forest and high altitude grassland mosaic in the Serra da Igreja, Southern Brazil. An Acad Bras Cienc. 2013;85:769-83.

[26] Silva AC, Horák I, Cortizas AM, Vidal-Torrado P, Racedo JR, Grazziotti PH, Silva EB, Ferreira CA. Turfeiras da Serra do Espinhaço Meridional-MG: I - Caracterização e classificação. Rev Bras Cienc Solo . 2009;33:1385-98. doi:10.1590/S0100-06832009000500030
» https://doi.org/10.1590/S0100-06832009000500030

[27] Silva FC, organizador. Manual de análises químicas de solos, plantas e fertilizantes. Brasília, DF: Embrapa Informação Tecnológica; 2009.

[28] Silva ML, Silva AC, Silva BPC, Barral UM, Soares PGS, Vidal-Torrado P. Surface mapping, organic matter and water stocks in peatlands of the Serra do Espinhaço Meridional - Brazil. Rev Bras Cienc Solo . 2013;37:1149-57. doi:10.1590/S0100-06832013000500004
» https://doi.org/10.1590/S0100-06832013000500004

[29] Simas FNB, Schaefer CEGR, Fernandes EI, Chagas AC, Brandão PC. Chemistry, mineralogy and micropedology of highland soils on crystalline rocks of Serra da Mantiqueira, southeastern Brazil. Geoderma. 2005;125:187-201. doi:10.1016/j.geoderma.2004.07.013
» https://doi.org/10.1016/j.geoderma.2004.07.013

[30] Soil Survey Staff. Keys to soil taxonomy. 12th ed. Washington, DC: United States Department of Agriculture, Natural Resources Conservation Service; 2014.

[31] Weissert LF, Disney M. Carbon storage in peatlands: A case study on Isle of Man. Geoderma . 2013;204:111-9. doi:10.1016/j.geoderma.2013.04.016
» https://doi.org/10.1016/j.geoderma.2013.04.016

Profile	Horizon	Depth	Munsell color	Texture class	Construction	Von Post		RF	PI
Profile	Horizon	Depth	Munsell color	Texture class	Construction	Index	Material
			m					%
Organossolo Háplico Hêmico típico (Haplohemists)								%
RJ-01	H₁	0.00-0.12	10YR 3/2	Organic material	Mod, m/co, granular	H₆	Hemic	30	5
	H₂	0.12-0.31	10YR 3/2	Organic material	Mod, m, granular	H₆	Hemic	27	4
	H₃	0.31-0.58	10YR 3/2	Organic material	Mod, m, angular blocky	H₆	Hemic	25	4
	Cg₁	0.58-0.76	10YR 3/2	Clay loam	Massive	H₇	Sapric	14	3
	Cg₂	0.76-1.0+	10YR 3/2	Clay loam	Massive	H₈	Sapric	15	3
			Organossolo Fólico Sáprico cambissólico (Udifolists)
RJ-02	O₁	0.00-0.15	N2/	Organic material	Mod, p/m, granular	H₈	Sapric	31	3
	O₂	0.15-0.28	N2	Organic material	Mod, f, granular	H₈	Sapric	18	3
	O₃	0.28-0.59	N2	Organic material	Weak, f, subangular blocky	H₉	Sapric	17	3
	Bw₁	0.59-0,85	N2	Clay loam	Weak, f/m, angular blocky	H₉	Sapric	17	3
	Bw₂/BC	0.85-1.0+	N4	Clay loam	Weak, f/m, angular blocky	H₉		Sapric	15	3

Profile	Horizon C H N C/N C-HUM C-HAF C-FAF					C-HAF/C-FAF
% g kg^-1
Organossolo Háplico Hêmico típico (Haplohemists)
RJ-01	H₁16.72 2.95			0.96	17.41	165.24	4.54 6.425		0.71
	H₂14.48 2.83			0.72	20.11	131.73	5.48 6.235		0.88
	H₃10.01 2.39			0.47	21.29	70.68	5.93 6.575		0.90
	Cg₁6.49 1.98			0.33	19.66	17.12	5.29 5.365		0.99
	Cg₂7.39 2.11			0.40	18.47	41.91	5.86 5.575		1.05
	Organossolo Fólico Sáprico cambissólico (Udifolists)								1.05
RJ-02	O₁	16.99	2.87	0.90	18.87	159.43	2.98	2.22	1.04
	O₂	10.56	2.32	0.60	17.60	64.42	3.59	2.65	1.36
	O₃	7.10	1.54	0.32	22.18	41.77	2.46	2.08	1.18
	Bw₁	4.56	1.16	0.18	25.33	22.75	1.47	1.21	1.22
	Bw₂/BC	2.77	0.78	0.11	25.18	15.71	2.61	2.46	1.06

Profile	Horizon	pH(H₂O) Ca²⁺Mg²⁺Al³⁺H⁺Na K P SB T					V
		cmol_c kg^-1 mg kg^-1 cmol_c kg^-1					%
Organossolo Háplico Hêmico típico (Haplohemists)
RJ-01	H₁	4.6	0.6	1.2	6.0	24.3	0.2	0.3	4.0	2.5	32.9	7
	H₂	4.6	0.5	1.1	4.3	25.2	0.2	0.1	1.0	2.1	31.7	6
	H₃	4.4	0.8	1.4	3.3	18.3	0.2	0.0	1.0	2.6	24.3	18
	Cg1	4.4	0.7	1.0	1.5	10.7	0.2	0.0	0.0	2.0	14.3	14
	Cg2	4.9	0.9	1.4	1.5	12.5	0.1	0.0	1.0	2.5	16.6	15
Organossolo Háplico Hêmico típico (Haplohemists)
RJ-02	O₁	5.0	0.3	0.9	1.7	11.5	0.3	0.2	1.0	1.8	15.1	15	11
	O₂	5.3	0.2	1.1	1.3	10.6	0.2	0.5	1.0	2.2	14.2	15
	O₃	5.4	0.2	0.9	1.6	10.5	0.2	0.1	1.0	1.5	13.7	11
	Bw₁	5.1	0.2	0.9	1.5	7.1	0.2	0.1	1.0	1.5	10.2	15
	Bw₂/BC	5.4	0.3	0.8	1.3	5.5	0.2	0.1	1.0	1.4	8.3	17

Profile	Horizon	Bd	Pd	OMD	MR	Gm	MM	TPV	SOM
		------------------- Mg m-3 -------------------			m m-1	------------------------------ % ------------------------------
Organossolo Háplico Hêmico típico (Haplohemists)					m m-1
RJ-01	H1	0.60	1.56	0.23	0.25	18.48	61.14	61.14	38.86
	H2	0.70	1.60	0.26	0.30	28.04	63.51	56.13	36.49
	H3	0.70	1.72	0.19	0.34	14.42	73.00	59.63	27.00
	Cg1	0.74	2.00	0.13	0.41	11.98	82.42	63.10	17.58
	Cg2	0.82	1.92	0.18	0.43	12.61	78.27	57.15	21.73
Organossolo Fólico Sáprico cambissólico (Udifolists)					0.43	12.61	78.27	57.15	21.73
RJ-02	O1	0.54	1.55	0.24	0.20	45.14	55.73	65.30	44.27
	O2	0.54	1.69	0.23	0.21	40.45	58.01	68.02	41.99
	)3	0.81	1.89	0.15	0.44	21.65	81.75	56.96	18.25
	Bw1	0.95	1.98	0.10	0.56	8.93	89.22	52.13	10.78
	Bw2/BC	1.17	2.15	0.41	0.50	10.13	64.65	45.69	35.35

Brasil

Brasil

Histosols in an Upper Montane Environment in the Itatiaia Plateau

ABSTRACT:

INTRODUCTION

MATERIALS AND METHODS

Characterization of the área

Soil sampling and analyses

RESULTS AND DISCUSSION

Morphological properties and SOM characterization (SiBCS)

Chemical and physical properties

Distribution of C, N, and carbon fractions in humic substances

Isotopic composition of carbon and nitrogen, and dating of humin via 14C

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

How to cite:

Publication Dates

History

Isotopic composition of carbon and nitrogen, and dating of humin via ¹⁴C