Acessibilidade / Reportar erro

Analysis of Potential for Linear Erosion in the Cerrado Biome Using Morphopedology

ABSTRACT

The Cerrado is a vegetation complex with a wide variety of phytophysiognomies, and sustainable management is essential for maintaining biodiversity. Morphopedology is a tool that can assist in developing plans for control of soil and land use, especially in evaluating the potential of soil erosion processes. This technique allows landscape units considered “homogeneous” to be distinguished, as a result of interaction between physiographic conditions. The aim of this study was to evaluate potential for erosion in São Miguel do Araguaia, state of Goiás, Brazil, through definition of morphopedological compartments (MPC), on the assumption that soil use has increased erosion. Landscape units were identified through use of geology overlay, hypsometry, slope, geomorphology, soil, and land use. The map information on a 1:100,000 scale was refined, the base of which was available in the Geographic Information System of Goiás. The morphopedological approach enabled identification of five MPC. Predominant soil classes in São Miguel do Araguaia (with matching categories) are Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), Plintossolos Pétricos Concrecionários (Petronodic Haplargids), Plintossolos Háplicos Distróficos (Plinthic Haplaquox), Gleissolos Háplicos Tb Distróficos (Typic Endoaquents), and Neossolos Quartzarênicos Órticos (Typic Quartzipsamments). Generally, every class of soil has some type of limitation that may cause erosion to different degrees. The most dissected areas are associated with lateritic covers, which suggests the importance of these features on topographical formation. The results of analysis of erosion susceptibility and linear erosion potential suggest low risk of erosion, even considering human activities, especially cattle ranching.

erosivity; erodibility; pedology; geomorphology; soil science

INTRODUCTION

The Cerrado (broadly, Brazilian tropical savanna) is Brazil’s second largest biome in area, occupying 2,000,000 km 2 , or 23 % of the country’s territory ( Ribeiro and Walter, 2008Ribeiro JF, Walter BMT. As principais fitofisionomias do bioma Cerrado. In: Sano SM, Almeida SP, Ribeiro JF editores. Cerrado: ambiente e flora. Planaltina: Embrapa - Cerrados; 2008. p.152-212. ). This biome has a vegetation complex with a wide diversity of phytophysiognomies, including forests, bushland, and fields, divided into several subtypes ( Ribeiro and Walter, 2008Ribeiro JF, Walter BMT. As principais fitofisionomias do bioma Cerrado. In: Sano SM, Almeida SP, Ribeiro JF editores. Cerrado: ambiente e flora. Planaltina: Embrapa - Cerrados; 2008. p.152-212. ). Encompassing the entire state of Goiás, the Cerrado has been degradated to various degrees, mainly from agricultural expansion, resulting in the loss of native vegetation.

Goiás is the state with the lowest remaining percentage of its original physiognomy of the Cerrado biome ( Sano et al., 2008Sano EE, Dambrós LA, Oliveira GC, Brites RS. Padrões de cobertura de solos do Estado de Goiás. In: Ferreira Júnior LG, organizador. A encruzilhada socioambiental: biodiversidade, economia e sustentabilidade no Cerrado. Goiânia: Universidade Federal de Goiás; 2008. p.85-100. ). In the northwest of the state, livestock has gained prominence, and part of the native vegetation has cleared to make way for new pasture. In 2007, the municipality of São Miguel do Araguaia had a deforested area of approximately 924 ha, representing 15 % of its territory ( Silva and Ferreira Júnior, 2010Silva EB, Ferreira Júnior LG. Taxas de desmatamento e produção agropecuária em Goiás - 2003 a 2007. Mercator. 2010;9:121-34. https://doi.org/10.4215/RM2010.0918.0010
https://doi.org/10.4215/RM2010.0918.0010...
).

Erosion tends to accelerate after native vegetation has been removed, especially when favored by soil properties, soil relief, climate, and land use ( Dotterweich, 2013Dotterweich M. The history of human-induced soil erosion: Geomorphic legacies, early descriptions and research, and the development of soil conservation - A global sinopsis. Geomorphology. 2013;201:1-34. https://doi.org/10.1016/j.geomorph.2013.07.021
https://doi.org/10.1016/j.geomorph.2013....
; Wang et al., 2013Wang B, Zheng F, Römkens MJM, Darboux F. Soil erodibility for water erosion: a perspective and Chinese experiences. Geomorphology. 2013;187:1-10. https://doi.org/10.1016/j.geomorph.2013.01.018
https://doi.org/10.1016/j.geomorph.2013....
). The erosive processes cause environmental changes that affect food production and the conservation of natural resources ( Latrubesse et al., 2009Latrubesse EM, Amsler MI, Morais RP, Aquino S. The geomorphologic response of a large pristine alluvial river to tremendous deforestation in the South American tropics: the case of the Araguaia River. Geomorphology. 2009;113:239-52. https://doi.org/10.1016/j.geomorph.2009.03.014
https://doi.org/10.1016/j.geomorph.2009....
; Coe et al., 2011Coe MT, Latrubesse EM, Ferreira ME, Amsler ML. The effects of deforestation and climate variability on the streamflow of the Araguaia River, Brazil. Biogeochemistry. 2011;105:119-31. https://doi.org/10.1007/s10533-011-9582-2
https://doi.org/10.1007/s10533-011-9582-...
); the productive potential of some regions may decrease as a result of increased intensity of erosion ( Lohmann and Santos, 2005Lohmann M, Santos LJC. A morfopedologia aplicada à compreensão dos processos erosivos na bacia hidrográfica do Arroio Guassupi, São Pedro do Sul - RS. Rev Bras Geomorfol. 2005;6:91-102. ).

Erosion varies depending on time and space; some erosive events leave marks on the landscape, which have also been linked to changes in land use and climate ( Dotterweich, 2013Dotterweich M. The history of human-induced soil erosion: Geomorphic legacies, early descriptions and research, and the development of soil conservation - A global sinopsis. Geomorphology. 2013;201:1-34. https://doi.org/10.1016/j.geomorph.2013.07.021
https://doi.org/10.1016/j.geomorph.2013....
). These erosive processes are caused by both natural and anthropogenic factors ( Wang et al., 2013Wang B, Zheng F, Römkens MJM, Darboux F. Soil erodibility for water erosion: a perspective and Chinese experiences. Geomorphology. 2013;187:1-10. https://doi.org/10.1016/j.geomorph.2013.01.018
https://doi.org/10.1016/j.geomorph.2013....
; Comino et al., 2016Comino JR, Iserloh T, Lassu T, Cerdà A, Keestra SD, Prosdocimi M, Brings C, Marzen M, Ramos MC, Senciales JM, Sinoga JDR, Seeger M, Ries JB. Quantitative comparison of initial soil erosion processes and runoff generation in Spanish and German vineyards. Sci Total Environ. 2016;565:1165-74. https://doi.org/10.1016/j.scitotenv.2016.05.163
https://doi.org/10.1016/j.scitotenv.2016...
; Mhazo et al., 2016Mhazo N, Chivenge P, Chaplot V. Tillage impact on soil erosion by water: discrepancies due to climate and soil characteristics. Agric Ecosyst Environ. 2016;230:231-41. https://doi.org/10.1016/j.agee.2016.04.033
https://doi.org/10.1016/j.agee.2016.04.0...
). The former, especially rain, vegetation cover, soil relief, soil types, and the geological substrate, determine the intensity of the process over the long term. The most notable anthropogenic aspects are deforestation, the use of certain soil types, and land occupation ( Latrubesse et al., 2009Latrubesse EM, Amsler MI, Morais RP, Aquino S. The geomorphologic response of a large pristine alluvial river to tremendous deforestation in the South American tropics: the case of the Araguaia River. Geomorphology. 2009;113:239-52. https://doi.org/10.1016/j.geomorph.2009.03.014
https://doi.org/10.1016/j.geomorph.2009....
; Coe et al., 2011Coe MT, Latrubesse EM, Ferreira ME, Amsler ML. The effects of deforestation and climate variability on the streamflow of the Araguaia River, Brazil. Biogeochemistry. 2011;105:119-31. https://doi.org/10.1007/s10533-011-9582-2
https://doi.org/10.1007/s10533-011-9582-...
).

Direct measurement of soil erodibility requires long-term studies of erosion, which are expensive and time-consuming ( Bonilla and Johnson, 2012Bonilla CA, Johnson OI. Soil erodibility mapping and its correlation with soil properties in Central Chile. Geoderma. 2012;189-190:116-23. https://doi.org/10.1016/j.geoderma.2012.05.005
https://doi.org/10.1016/j.geoderma.2012....
). Morphopedology could enable assessment of the potential for water erosion, especially the potential for and susceptibility to linear erosion, assisting in the development of public policies aimed at agricultural production and natural resource preservation. Morphopedology is a tool that assists in the development of soil use and occupation control plans, particularly related to environmental preservation. The technique enables us to spatialize landscape units considered “homogeneous” by investigating the interaction among geological substrates, soil relief, and soil types ( Castro and Salomão, 2000Castro SS, Salomão FXT. Compartimentação morfopedológica e sua aplicação: considerações metodológicas. Geousp. 2000;7:27-37. https://doi.org/10.11606/issn.2179-0892.geousp.2000.123401
https://doi.org/10.11606/issn.2179-0892....
).

Some morphopedological studies on erosion have been based on the relationship between the geological substrate, soil relief, soil type, slope, and land use. Ribeiro and Salomão (2003)Ribeiro JC, Salomão FXT. Abordagem morfopedológica aplicada ao diagnóstico e prevenção de processos erosivos na bacia hidrográfica do Alto Rio da Casca, MT. Geociências. 2003;22:83-95. described the morphopedological compartments (MPC) of the upper Casca River, in the state of Mato Grosso, to assess the susceptibility of this area to linear erosion caused by the concentration of water flow lines, which may evolve into grooves or gullies. Lohmann and Santos (2005)Lohmann M, Santos LJC. A morfopedologia aplicada à compreensão dos processos erosivos na bacia hidrográfica do Arroio Guassupi, São Pedro do Sul - RS. Rev Bras Geomorfol. 2005;6:91-102. sought to use morphopedological compartmentalization to assess the genesis and evolution of erosion in the Arroyo Guassupi watershed in the municipality of São Pedro do Sul (RS). Hermuche et al. (2009)Hermuche PM, Guimarães GMA, Castro SS. Análise dos compartimentos morfopedológicos como subsídio ao planejamento do uso do solo em Jataí - GO. Geousp. 2009;26:113-31. https://doi.org/10.11606/issn.2179-0892.geousp.2009.74131
https://doi.org/10.11606/issn.2179-0892....
used morphopedological compartmentalization to assess susceptibility to linear erosion in the municipality of Jataí (GO) and presented a proposal for land use planning employing this technique.

Based on the assumption that land use and occupation have affected linear erosion in Cerrado Biome, this study aims to use morphopedological compartmentalization to assess the erosion potential in the municipality of São Miguel do Araguaia in northwestern Goiás, Brazil.

MATERIAL AND METHODS

Description of the research site

The study was conducted in the municipality of São Miguel do Araguaia, in northwestern Goiás, Brazil, located in the Araguaia river basin ( Figure 1 ). The municipality has an area of 614,7 26 ha and a population of 22,283; 79 % of whom are concentrated in the urban area, and an overall population density of 3.63 inhabitants per km 2 ( IBGE, 2016Instituto Brasileiro de Geografia e Estatística - IBGE. Coordenação de recursos naturais e estudos ambientais. Cidades@ [internet]. Brasília, DF: Instituto Brasileiro de Geografia e Estatística; 2016 [acesso em 21 set 2016]. Disponível em: http://www.cidades.ibge.gov.br/xtras/perfil.php?lang=&codmun=522020&search=goias|sao-miguel-do-araguaia.
http://www.cidades.ibge.gov.br/xtras/per...
). The regional climate is type Aw, characterized as tropical savanna ( Köppen, 1948Köppen W. Climatologia: com un estudio de los climas de la tierra. México: Fondo de Cultura Economica; 1948. ), with average annual rainfall of 1,640 mm and average annual temperature of 26.8 °C.

Figure 1
Location of the municipality of São Miguel do Araguaia, state of Goiás, Brazil.

The vegetation is predominantly composed of grasslands associated with dense Cerrado and murundus (termite mounds) in addition to trees, with more than 50 % of coverage exceeding 5 m in height. The region’s typical physiognomy is savanna, divided into closed savanna with murundus , and open savanna with murundus ( Ribeiro and Walter, 2008Ribeiro JF, Walter BMT. As principais fitofisionomias do bioma Cerrado. In: Sano SM, Almeida SP, Ribeiro JF editores. Cerrado: ambiente e flora. Planaltina: Embrapa - Cerrados; 2008. p.152-212. ).

Flat terrain represents 81 % of the territory in the municipality, and 19 % is rolling terrain; the municipality also encompasses the Araguaia Depression, a slightly rolling area typical of the Araguaia River plain. Altitude in the region ranges from 180 to 480 m, with the highest elevations located in the center of the research site.

The soil types Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox) represent 60 % of the area and are associated with the surface of the Lower Araguaia Group. Plintossolos Pétricos Concrecionátios (Petronodic Haplargids), followed by Plintossolos Háplicos Alumínicos (Plinthic Haplaquox), cover 38.6 % of the area and are associated with the Araguaia Formation. Gleissolos Háplicos Distróficos (Typic Endoaquents) are associated with alluvial deposits and account for 0.9 % of the area, followed by Neossolos Quartzarênicos Órticos (Typic Quartzipsamments), which are located in the southeastern area of the municipality and make up 0.3 % of the total area ( Table 1 ).

Table 1
Soil classes in the municipality of São Miguel do Araguaia, state of Goiás, Brazil

Geomorphological features are divided into three categories ( Table 1 ). Areas associated with surface planing, with dissections ranging from very weak to average ( Figure 2 ) and from 200 to 400 m altitude, occupy approximately 481,117 ha. The areas where sediments have been deposited (aggradation), associated with lower surfaces, were characterized by fluvial tracks, sediment banks, and meandering patterns and cover 123,600 ha. Finally, areas marked by the presence of folded structures forming hogbacks cover 830 ha.

Figure 2
Texture aspects on shaded SRRM images ( shade-relief ), indicating the degree of dissection of the municipality of São Miguel do Araguaia, state of Goiás, Brazil. (a) Very weak dissection (mfr); (b) Weak dissection (fr); and (c) Medium dissection (m).

The most common geological units are the Lower Araguaia Group (NPx), predominantly consisting of schist (57 %); the Araguaia - Facies fluvial deposits (Qag2), formed from clay, silt, and sand (28 %); alluvial deposits (Q2a) associated with areas of lower elevation, formed from deposits of sand and gravel (8 %); the plutonic complex of the Goiás volcanic arc - orthogneiss unit of the west of Goiás (NP1), which contains gneiss, tonalite, and granite (3 %); ferruginous lateritic detritus (N1d1), formed from agglomerations, laterites, clay, and sand (3 %); and the Agua Bonita formation (Sdab), formed from sandstone, conglomerate, and siltstone (1 %) ( Brasil, 1981Brasil. Ministério das Minas e Energia. Projeto RADAMBRASIL. Levantamento de Recursos Naturais. Folha SC. 22. Tocantins: Geologia, geomorfologia, pedologia, vegetação e uso potencial da terra. Rio de Janeiro: 1981. ).

Methodological criteria of mapping

The mapping procedures were divided into two stages: the first consisted of describing the physiographic units of the municipality in order to determine the morphopedological compartments, while the second assessed the potential for linear erosion based on the compartments established. These procedures are summarized in the flowchart shown in figure 3 .

Figure 3
Flowchart of the cartographic procedures adopted to generate the map of linear erosion potential of the municipality of São Miguel do Araguaia, state of Goiás, Brazil.

Morphopedological compartmentalization

Landscape units were identified through the overlaying of geology, hypsometry, slope, geomorphology, soils, and land use. The cartographic information was shown on a scale of 1:100,000, based on data from the Geographic Information System of Goiás ( SIEG, 2015Sistema Estadual de Geoinformação - SIEG. [internet]. Goiânia, GO: 2015 [acesso em 20 nov 2015]. Disponível em: https://www.sieg.go.gov.br/.
https://www.sieg.go.gov.br/...
). Images from Landsat 8 OLI with orbit 223 and point 69 of 2015, available in the United States Geological Survey (USGS), were used. After images calibration and the reflectance values processing, the land use map was developed with segmentation, and classification was generated using the ENVI ® 5 software.

The hypsometry and slope maps were drawn in ArcGIS ® 10.1 software based on data from the Digital Ground Model (DGM) generated by the Shuttle Radar Relief Mission (SRRM), with resolution of 30 m, and made available by INPE (2015)Instituto Nacional de Pesquisas Espaciais - INPE. Topodata [internet]. Brasília, DF: Ministério da Ciência, Tecnologia, Inovações e Comunicações; 2015 [acesso em 20 nov 2015]. Disponível em: http://www.webmapit.com.br/inpe/topodata/.
http://www.webmapit.com.br/inpe/topodata...
. The levels of dissection were determined by identifying other important features of soil relief, according to the IBGE (2009)Instituto Brasileiro de Geografia e Estatística - IBGE. Manual técnico de geomorfologia. 2ª ed. Rio de Janeiro: Coordenação de recursos naturais e estudos ambientais; 2009. , with a few adaptations. The mapping units contained in each compartment were delineated with soil maps used as a database, and were developed and refined based on 13 control points (soil profiles), in addition to field observations and assessment of physiographic data.

The maps used as a database for compartmentalization, as well as the boundaries of each morphopedological compartment, are in figure 4 . The map combination function of the Modelbuilder tool was used to superpose cartographic information and delineate each morphopedological compartment. Additionally, topographical profiles were plotted for each MPC to highlight the altimetry in greater scale, together with aspects related to soils and features of soil relief.

Figure 4
Physiographic maps (geology, geomorphology, soils, hypsometry, and slope) of the municipality of São Miguel do Araguaia, Goiás, Brazil.

Assessment of susceptibility to linear erosion

The assessment of susceptibility to linear erosion was based on the method proposed by Salomão (1999)Salomão FXT. Controle e prevenção dos processos erosivos. In Guerra AJT, Silva AS, Botelho RGM, organizadores. Erosão e conservação dos solos: conceitos, temas e aplicações. Rio de Janeiro: Bertrand Brasil; 1999. p. 229-67. , in which the degree of erodibility is generated according to each pedological unit, as described below: II - Weak: Plintossolos Háplicos (FXa1, FXa2, FXd) and Gleissolos Háplicos (GXbd1, GXbd2), corresponding to an area of 141,840 ha (24.4 % of the municipality); III - Moderate: Plintossolos Pétricos (FFc1) and Latossolos Vermelho-Amarelos (LVAd1, LVAd2), corresponding to an area of 418,612 ha (72.2 % of the municipality); IV - Strong: Plintossolos Pétricos (FFc2), corresponding to an area of 17,647 ha (3.0 % of the municipality); and V - Very Strong: Neossolos Litólicos (RQo), corresponding to an area of 2,040 ha (0.4 % of the municipality).

The susceptibility map was generated using data on land slope, in which the susceptibility of land with 0 to 3 % slope was defined as I - Very Weak, representing 42.8 % of the municipality (263,310 ha); the susceptibility of land with 3 to 8 % slope was considered II - Weak, corresponding to 49.4 % of the municipality (303,853 ha); the susceptibility of land with 8 to 20 % slope was classified as III - Moderate, corresponding to 7.6 % of the municipality (46,884 ha); the susceptibility of land with 20 to 45 % slope was considered IV - Strong, corresponding to 0.1 % of the municipality (646 ha); and the susceptibility of land with >45 % slope was considered V - Very Strong, corresponding to 1 ha.

The classes of susceptibility to linear erosion were generated from the overlap of the erodibility and slope maps ( Table 2 ). Class I indicates areas extremely susceptible to erosion; Class II corresponds to very susceptible areas; Class III corresponds to moderately susceptible areas; Class IV corresponds to slightly susceptible areas; and Class V corresponds to those areas with little or no susceptibility to erosion.

Table 2
Description of the geomorphologic units of the municipality of São Miguel do Araguaia, state of Goiás, Brazil

Current land use was divided into four categories based on potential for causing erosion ( Salomão, 1999Salomão FXT. Controle e prevenção dos processos erosivos. In Guerra AJT, Silva AS, Botelho RGM, organizadores. Erosão e conservação dos solos: conceitos, temas e aplicações. Rio de Janeiro: Bertrand Brasil; 1999. p. 229-67. ): I - High potential, II - Moderate potential, III - Low potential, and IV - No potential ( Table 2 ). The potential for linear erosion was determined from the matrix of intersection between the classes of susceptibility and the categories of current land use.

RESULTS AND DISCUSSION

After identifying and delineating the landscape units from an integrated analysis of data collected from charts, satellite imagery, and field observations, five morphopedological compartments were established ( Figure 5 ), as described below:

Figure 5
Morphopedological compartment maps, current use, susceptibility to erosion, and erosion potential in the municipality of São Miguel do Araguaia, state of Goiás, Brazil.

MPC-I: top of plateau, with a moderately dissected surface associated with lateritic cover and the presence of Latossolos Vermelhos Distróficos (Rhodic Haplustox) and Plintossolos Pétricos Concrecionários (Petronodic Haplargids). This MPC has an area of 80,960 ha, representing 13.3 % of the territory of the municipality;

MPC-II: A slightly to very slightly dissected surface, associated with unconsolidated ferruginous features with the presence of Latossolos Vermelhos Distróficos (Rhodic Haplustox) and Plintossolos Háplicos Distróficos (Plinthic Haplaquox). This MPC has an area of 287,481 ha, corresponding to 47.2 % of the territory of the municipality;

MPC-IIIa: Area of flat surface, part of the Araguaia River plain, associated with alluvial deposits, in which abandoned meanders are common, with the presence of Neossolos Quartzarênicos Órticos (Typic Quartzipsamments) and Plintossolos Háplicos Alumínicos (Plinthic Haplaquox). This MPC has an area of 173,481 ha, corresponding to 28.5 % of the territory of the municipality;

MPC-IIIb: Area of flat surface, associated with Holocene sediments, with the presence of Plintossolos Háplicos Alumínicos (Plinthic Haplaquox), Gleissolos Háplicos Tb Distróficos (Typic Endoquents), Argissolos Vermelho-Amarelos Distróficos (Xanthic Kandiudox), and Latossolos Vermelhos Distróficos (Rhodic Haplustox). This MPC has an area of 25,036 ha, corresponding to 4.1 % of the territory of the municipality; and

MPC-IV: Area of slightly dissected surface, associated with lateritic cover, with the presence of Latossolo Vermelho Distrófico plintossólico (Plinthic Hapludox), Plintossolo Pétrico Concrecionário (Petronodic Haplargids), and Gleissolo Háplico Tb Distrófico (Typic Endoquents). This MPC has an area of 41,794 ha, corresponding to 6.9 % of the territory of the municipality.

MPC-II, an area with slight dissection, represents the largest portion of the research site, followed by MPC-IIIa, which has a flat surface, in an area where the water table level oscillates due to its proximity to the Araguaia River. The degree of dissection of soil relief is associated with the development of thalwegs, which can be linked to environmental changes such as Pleistocene glacio-eustatic oscillations and tectonic effects ( Casseti, 2005Casseti V. Geomorfologia. Goiânia, GO: FUNAPE; 2005 [acesso em 01 dez 2016]. Disponível em: http://www.funape.org.br/geomorfologia.
http://www.funape.org.br/geomorfologia...
).

Topographical profiles were plotted in the most representative areas of each compartment in order to demonstrate the occurrence of pedological units along a transect. Thus, MPC-I (A-B) corresponds to the top area ( Figure 6 ), with the highest elevation in the municipality and predominance of Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), followed by Plintossolos Pétricos Concrecionários (Petronodic Haplargids) alternating through the landscape, and includes other types associated with the mapping units. In general, this region has average dissection, possibly at the expense of the structural control provided by the laterite cover that influences the morphogenesis of the landscape ( Bigarella et al., 1996Bigarella JJ, Becker RD, Passos E. Estrutura e origem das paisagens tropicais e subtropicais: Intemperismo biológico, pedogênese, laterização, bauxitização e concentração de bens minerais. Florianópolis: Universidade Federal de Santa Catarina; 1996. ). The dissection of soil relief is shaped by tectonic effects, possibly by positive epeirogeny, creating a steeper slope and increasing the intensity of erosion ( Casseti, 2005Casseti V. Geomorfologia. Goiânia, GO: FUNAPE; 2005 [acesso em 01 dez 2016]. Disponível em: http://www.funape.org.br/geomorfologia.
http://www.funape.org.br/geomorfologia...
). The tectonic effect can be confirmed by marks found on exposed rocks in the most dissected areas of the municipality, and especially by the presence of metamorphosed rocks ( Brasil, 1981Brasil. Ministério das Minas e Energia. Projeto RADAMBRASIL. Levantamento de Recursos Naturais. Folha SC. 22. Tocantins: Geologia, geomorfologia, pedologia, vegetação e uso potencial da terra. Rio de Janeiro: 1981. ).

Figure 6
Representative topographic profiles with soil sequences from the municipality of São Miguel do Araguaia, state of Goiás, Brazil.

The degree of slope observed in the most dissected areas is a factor considered in predictive mathematical modeling of soil erosion, such as the Universal Soil Loss Equation (USLE), which justifies of use od degree of slope as evidence of erosion ( Wischmeier and Smith, 1978Wischmeier WH, Smith DD. Predicting rainfall erosion losses: a guide to conservation planning. Washington, DC: USDA; 1978. (Agricultural handbook, 537). ; Moreti et al., 2003Moreti D, Carvalho MP, Mannigel AR, Medeiros LR. Importantes características de chuva para a conservação do solo e da água no município de São Manuel (SP). Rev Bras Cienc Solo. 2003;27:713-25. http://dx.doi.org/10.1590/S0100-06832003000400016
http://dx.doi.org/10.1590/S0100-06832003...
).

Although Latossolos (Oxisols) are predominant in MPC-I (A-B), they have hardened ferruginous concretions (petroplinthite), characteristics associated with a highly porous matrix with a granular structure, resulting in greater infiltration of water. However, the vertical flow is stopped when contact with the laterite layer or lithoplinthic horizon; thus, more pronounced slopes can result in runoff, causing particle drag (erosive processes). This occurs is also observed in Plintossolos Pétricos Concrecionários (Petronodic Haplargids) , although they provide a greater volume of petroplinthite, associated with other types of coarse fractions greater than 2 mm (fragments of quartz, associated with other minerals). The restriction of water infiltration occurs especially in the presence of the F horizon ( Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Oliveira JB, Coelho MR, Lumbreras JF, Cunha TJF. Sistema brasileiro de classificação de solos. 3a ed. Rio de Janeiro: Embrapa Solos; 2013. ) at various positions in the soil profile, and this horizon controls the water flow, depending on the depth at which it occurs.

In MPC-II (C-D; C’-D’), the most common soils types are Plintossolos Pétricos Concrecionários (Petronodic Haplargids), followed by Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), associated with laterite cover and a moderate process of landscape dissection ( Figure 6 ). The physio-hydric pattern of this compartment is analogous to that of MPC-I; however, the slope becomes the main aggravating factor in the erosive process, which corroborates the greater degree of dissection observed in this compartment. This shows that the erosive process is more pronounced here than in MPC-I, despite the presence of a more stable cover.

MPC-IIIa (G-H) is predominantly characterized by Plintossolos Háplicos Distróficos (Plinthic Haplaquox), and these areas have the lowest elevation in the municipality ( Figure 6 ). Despite being located at the same elevation, MPC-IIIb (I-J) may be more influenced by the water flow and sediment from the Araguaia River. These areas of lower elevation have low hydraulic conductivity; in the case of Plintossolos Háplicos (Plinthic Haplaquox), the soil texture with predominance of silt and clay fractions leads to this result, although the slope of the terrain reduces the surface runoff, reducing particle drag.

In MPC-IIIb (I-J), the most common soil types are Plintossolos Háplicos Distróficos (Plinthic Haplaquox), associated with dystrophic Gleissolos Háplicos Tb Distróficos plintossólicos (Plinthic Haplaquox) ( Figure 6 ). Both include marked ferruginous and manganous features from oscillation of the water table, along with a source of Fe and Mn in the soil solution. These features result from the segregation, mobilization, transport, and concentration of Fe and Mn ions and compounds ( Coelho et al., 2001Coelho MR, Vidal-Torrado P, Ladeira FSB. Macro e micromorfologia de ferricretes nodulares desenvolvidos de arenito do Grupo Bauru, Formação Adamantina. Rev Bras Cienc Solo. 2001;25:371-85. https://doi.org/10.1590/S0100-06832001000200013
https://doi.org/10.1590/S0100-0683200100...
). The class of Plintossolos Háplicos Distróficos (Plinthic Haplaquox) has characteristics that resemble those in MPC-IIIa, but they differ due to the juvenility of the source material. The meander features are clearly visible on the satellite image, in contrast to MPC-IIIa.

The Gleissolos (Entisols) class located in MPC-IIIb was subjected to hydromorphism and has a variable texture, primarily formed in this case by alluvial sediments, due to the proximity of the Araguaia River. These soils vary from poorly to very poorly drained, and may have plinthic features within a 1.00 m depth, or a plinthic horizon under the control section ( Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Oliveira JB, Coelho MR, Lumbreras JF, Cunha TJF. Sistema brasileiro de classificação de solos. 3a ed. Rio de Janeiro: Embrapa Solos; 2013. ).

MPC-IV contains Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), followed by Plintossolos Pétricos Concrecionários (Petronodic Haplargids) in the most dissected areas ( Figure 6 ). This compartment has characteristics similar to MPC-II, especially with regards to its physical properties, which shaped the hydraulic dynamic. Additionally, the Plintossolos (Oxisols) with these characteristics have severe limitations in use, with low water storage capacity ( Coelho et al., 2012Coelho MR, Fontana A, Avanzi JC, Ummus ME, Martins ALS, Oliveira AP, Costa TV, Cirqueira ALO, Dart RO, Souza JS, Áglio MLD. Solos do campo experimental de Buritirana da Embrapa Pesca e Aquicultura, município de Palmas - TO. Rio de Janeiro: Embrapa Solos; 2012. (Boletim de pesquisa e desenvolvimento, 214). ). In their assessment of the erosivity and erodibility of soils in the region of Lavras (MG), Silva et al. (2009)Silva AM, Silva MLN, Curi N, Avanzi JC, Ferreira MM. Erosividade da chuva e erodibilidade de Cambissolo e Latossolo na região de Lavras, Sul de Minas Gerais. Rev Bras Cienc Solo. 2009;33:1811-20. https://doi.org/10.1590/S0100-06832009000600029
https://doi.org/10.1590/S0100-0683200900...
reported that although the Latossolos Vermelhos (Rhodic Haplustox) have greater permeability, there is little cohesion among the aggregates, resulting in high erosivity.

MPC-I consists mainly of mapping unit LVAd2, which contains Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox) with clayey texture, located in soil relief areas that range from flat to slightly rolling, along with Argissolos Vermelho-Amarelo Distróficos (Xanthis Kandiudox) with low-activity clay located in soil relief areas that range from flat to slightly rolling, and Latossolos Vermelho Distróficos (Rhodic Haplustox) with clayey texture located in soil relief areas ranging from flat to slightly rolling. Next in order of importance is unit FFc2, which contains Plintossolos Pétrico Concrecionário (Petronodic Haplargids) of a dystrophic nature, with low activity clay and medium texture, located in relief areas from slightly rolling to rolling, and Latossolo Vermelho-Amarelo Distrófico petroplíntico (Petronodic Haplargids) of medium texture in a slightly rolling relief, with inclusions in Latossolos Vermelho-Amarelo Distrófico petroplíntico (Petronodic Haplargids) with a clayey texture. In part of unit FFc1, Plintossolo Pétrico Concrecionário típico (Petronodic Haplargids) was observed with low-activity clay of medium texture. In addition, Latossolo Vermelho-Amarelo Distrófico petroplíntico (Petronodic Haplargids) of medium texture and Neossolos Litólico Distróficos (Typic Udorthents) with medium texture were found in a soil relief ranging from slightly rolling to rolling, along with Cambissolo Háplico Tb Distrófico petroplíntico (Petronodic Haplargids), with medium-texture, low-activity clay.

MPC-II is composed primarily of mapping units LVAd2 and FFc1, both described previously, plus unit LVAd1, characterized by Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), with medium texture, and Neossolos Litólicos Distróficos (Typic Udorthents) in slightly rolling soil relief. To a lesser extent, it includes units FFc2, RQo, and GXbd1, predominantly consisting of Plintossolo Pétrico Concrecionário típico (Petronodic Haplargids), Neossolo Quartzarênico Órtico (Typic Quartzipsamments), and Gleissolo Háplico Tb Distrófico plintossólico (Plinthic Haplaquox).

MPC-IIIa consists primarily of the mapping unit FXa2, characterized by Plintossolos Háplicos Alumínico (Plinthic Haplaquox), with low activity clay and clayey texture, followed by Plintossolo Argilúvico Alumínico abrúptico (Kandic Plinthaquults), with low activity clay and medium/clayey texture, and Planossolo Háplico Alumínico plintossólico (Plinthaquic Kandiustox), with low activity clay and medium/clayey texture. This unit is associated with flat soil relief, including Plintossolos Háplicos Distróficos (Plinthic Haplaquox), with low activity clay, medium/clayey texture, and Latossolo Amarelo Distrófico plintossólico (Plinthic Acraquox), with clayey texture. Additionally, unit LVAd1 makes up a large portion of MPC-IIIa, composed of Latossolos Vermelho-Amarelo Distróficos (Xanthis Hapludox), followed by unit FXd, characterized by Plintossolos Háplico Distróficos (Plinthic Haplaquox), with low activity clay, medium/clayey texture. This unit is associated with Latossolo Vermelho-Amarelo Distrófico plintossólico (Plinthic Acraquox), with clayey texture and Gleissolos Háplicos Tb Distróficos (Typic Endoquents), with low activity clay and clayey texture, on flat soil relief. To a lesser extent, there is unit GXbd1, composed of Gleissolo Háplico Tb Distrófico plintossólico (Plinthic Haplaquox) and Plintossolo Háplico Distrófico típico (Plinthic Haplaquox).

MPC-IIIb is composed of unit FXa1, characterized by Plintossolo Háplico Alumínico típico (Plinthic Haplaquox) with low activity clay, clayey texture, Plintossolo Argilúvico Alumínico abrúptico (Kandic Plinthaquults), with low activity clay, medium/clayey texture, and Planossolo Háplico Alumínico with plinthic features (Plinthaquic Kandiustox), low activity clay, medium/clayey texture, on flat soil relief, where occur inclusions of Plintossolos Argilúvico Distróficos (Kandic Plinthaquults), with low activity clay, medium/clayey texture, and Latossolo Amarelo Distrófico plintossólico (Plinthic Acraquox) with clayey texture. The other mapping units that make up this compartment are FXd, GXbd2, FXa2 and LVAd1, all already described.

MPC-IV is composed of the mapping units LVAd2, with predominance of Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), followed by the units FFc1 and GXbd1, predominantly consisting of Plintossolos Pétricos Concrecionários (Petronodic Haplargids) and Gleissolos Háplicos Tb Distróficos (Typic Endoquents).

With regards to susceptibility to erosion, the areas of the municipality of São Miguel do Araguaia do not have aggravating factors, and are mostly classified as low to moderately susceptible ( Figure 5 ). It should be noted that the scale of this study may not include important data when creating the model, considering that the greater the scale used in data input (physiographic constraints), the greater the level of detail, especially with regards to the accuracy of assessment. These limitations are offset here by field observations and prior knowledge of the research site.

An area corresponding to approximately 0.3 % of the northeastern territory of the municipality was classified as extremely susceptible to erosion, coinciding with the soil type Neossolos Quartzarênicos (Typic Quartzipsamments). These soils are mainly composed of the sand fraction ( Santos et al., 2013Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Oliveira JB, Coelho MR, Lumbreras JF, Cunha TJF. Sistema brasileiro de classificação de solos. 3a ed. Rio de Janeiro: Embrapa Solos; 2013. ), which confers greater drag potential due to low cohesion among the particles. High risk of degradation can be inferred in this soil type due to its fragility, which may be accelerated by the removal of natural vegetation, especially arising from irregular agricultural practices or excessive trampling by cattle ( Silva et al., 2014Silva FL, Pierangeli MA, Santos FAS, Sousa JB, Serainm ME, Sousa CA. Caracterização pedológica de campos de murundus da bacia hidrográfica do rio Guaporé no estado de Mato Grosso. Rev Geon. (Ed Especial). 2014;10:51-8. ). In general, soil texture is an essential element in predicting its erosive potential ( Bonilla and Johnson, 2012Bonilla CA, Johnson OI. Soil erodibility mapping and its correlation with soil properties in Central Chile. Geoderma. 2012;189-190:116-23. https://doi.org/10.1016/j.geoderma.2012.05.005
https://doi.org/10.1016/j.geoderma.2012....
).

The yellow-shaded areas on the susceptibility map represent moderate susceptibility to linear erosion, almost always associated with the presence of petroplinthic soils and laterite cover. Some Plintossolos (Oxisols) have a subsurface horizon of type B texture (Bt), mostly due to the pedogenetic processes of clay eluviation and illuviation ( Nascimento et al., 2013Nascimento AF, Furquim SAC, Couto EG, Beirigo RM, Oliveira Junior JC, Camargo PB, Vidal-Torrado P. Genesis of textural contrasts in subsurface soil horizons in the Northern Pantanal-Brazil. Rev Bras Cienc Solo. 2013;37:1113-27. https://doi.org/10.1590/S0100-06832013000500001
https://doi.org/10.1590/S0100-0683201300...
; 2015Nascimento AF, Furquim SAC, Graham RC, Beirigo RM, Oliveira Junior JC, Couto EG, Vidal-Torrado P. Pedogenesis in a Pleistocene fluvial system of the Northern Pantanal - Brazil. Geoderma. 2015;255-256:58-72. https://doi.org/10.1016/j.geoderma.2015.04.025
https://doi.org/10.1016/j.geoderma.2015....
). This reduces the subsurface hydraulic conductivity and increases surface runoff, depending on the slope of the terrain and the rainfall. Both aspects are considered in the Universal Soil Loss Equation ( Wischmeier and Smith, 1978Wischmeier WH, Smith DD. Predicting rainfall erosion losses: a guide to conservation planning. Washington, DC: USDA; 1978. (Agricultural handbook, 537). ), a mathematical model which combines factors affecting soil erosion to predict soil loss, expressed in tons per hectare per year.

With regards to soil use ( Figure 5 ), most of the municipality is occupied by planted pastures, particularly Urochloa brizantha ( Table 3 ), with different levels of pasture degradation due to the high intensity of grazing. The areas covered by native species are grassland, almost always associated with murundus (termite mounds); they have been widely used for animal husbandry. Deforestation can change the hydrological cycle, geomorphological features, and biochemical flows, reducing evapotranspiration on the land surface and increasing surface runoff, soil erosion, and sediment flows ( Coe et al., 2011Coe MT, Latrubesse EM, Ferreira ME, Amsler ML. The effects of deforestation and climate variability on the streamflow of the Araguaia River, Brazil. Biogeochemistry. 2011;105:119-31. https://doi.org/10.1007/s10533-011-9582-2
https://doi.org/10.1007/s10533-011-9582-...
).

Table 3
Degree of erodibility by pedological units of the municipality of São Miguel do Araguaia, Goiás, Brazil

A portion of the municipality has low potential for linear erosion ( Figure 5 ). However, 50 % of the municipality is occupied by extensive ranching, which may contribute to the processes that trigger linear erosion. It is possible to establish appropriate soil use and management through awareness of the potential for and susceptibility to linear erosion, especially through use of conservation practices that mitigate water erosion ( Moreti et al., 2003Moreti D, Carvalho MP, Mannigel AR, Medeiros LR. Importantes características de chuva para a conservação do solo e da água no município de São Manuel (SP). Rev Bras Cienc Solo. 2003;27:713-25. http://dx.doi.org/10.1590/S0100-06832003000400016
http://dx.doi.org/10.1590/S0100-06832003...
). Given the predominant activity in the research site, the possibility of using integrated production systems to maintain soil quality, reduce soil loss, and minimize human impact on this portion of the Araguaia River basin should be considered.

The physiographic data and results of this analysis of erosive potential in the Cerrado biome are summarized and presented in table 4 .

Table 4
Degree of susceptibility according to classes of slope in the municipality of São Miguel do Araguaia, state of Goiás, Brazil
Table 5
Classes of susceptibility to linear erosion in the municipality of São Miguel do Araguaia, state of Goiás, Brazil
Table 6
Classes of potential for linear erosion in the municipality of São Miguel do Araguaia, state of Goiás, Brazil

Table 7
Criteria for defining the morphopedological compartments (MPC)

Table 8
Description of the types of soil present in the municipality of São Miguel do Araguaia, state of Goiás, Brazil

Table 9
Overview of the physiographic features and summary of the results of analysis of erosive potential in the Cerrado biome

In short, morphopedology is a technique that can contribute to interpretation of processes involving pedogenesis and morphogenesis when data is scarce, as in Brazil, especially with regards to erosion control and prevention, which could assist in development of public policies that target systems of agricultural production and natural resource preservation. The Cerrado biome is a complex system, particularly in the Araguaia River Basin, which has been the site of intense geomorphological changes resulting from anthropogenic action in recent decades. This anthropogenic action has triggered a rapid fluvial response and caused great environmental disruption ( Latrubesse et al., 2009Latrubesse EM, Amsler MI, Morais RP, Aquino S. The geomorphologic response of a large pristine alluvial river to tremendous deforestation in the South American tropics: the case of the Araguaia River. Geomorphology. 2009;113:239-52. https://doi.org/10.1016/j.geomorph.2009.03.014
https://doi.org/10.1016/j.geomorph.2009....
).

CONCLUSIONS

The most common soil types in the municipality of São Miguel do Araguaia are Latossolos Vermelho-Amarelo Distróficos (Xanthic Hapludox), Plintossolos Pétricos Concrecionários (Petronodic Haplargids), Plintossolos Háplicos Distróficos (Plinthic Haplaquox), Gleissolos Háplicos Tb Distróficos (Typic Endoquents), and Neossolos Quartzarênicos Órticos (Typic Quartzipsamments). In general, all soil types have some limitations, which may lead to varying degrees of erosion, depending on physio-hydric aspects and the slope of the land.

The most dissected areas are associated with laterite cover, suggesting the importance of these features in forming soil relief. In these areas, the F horizon or layer occurs at various positions in the soil profile; this variation in depth influences water flow, together with the slope of the terrain and the soil cover. These factors affect erosion and, consequently, the degree of dissection of the soil relief.

The morphopedology technique made it possible to identify and spatialize five morphopedological compartments that resulted from the interaction between physiographic conditions; this aided evaluation of linear erosion of the soil in an area used primarily for cattle ranching.

Results of analyses of susceptibility to and potential for linear erosion show low risk of erosion, even in areas affected by anthropogenic activity, particularly livestock raising, considering aspects related to prior knowledge of the area and the number of field observations.

ACKNOWLEDGMENTS

Our thanks to CAPES for awarding a fellowship to D. D. C. Maranhão and to the Organization of American States for awarding a fellowship to O. I. O. Aguado; to CPGA-CS and to the Laboratory of Soil Genesis and Classification of the UFRRJ; to CIAMB and to Laboratory of Image Processing and Geoprocessing of UFG for technical support.

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Publication Dates

  • Publication in this collection
    2017

History

  • Received
    22 Sept 2016
  • Accepted
    10 Jan 2017
Sociedade Brasileira de Ciência do Solo Secretaria Executiva , Caixa Postal 231, 36570-000 Viçosa MG Brasil, Tel.: (55 31) 3899 2471 - Viçosa - MG - Brazil
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