Correlation between land use and geomorphological features: a proposal of analysis using retrospective mapping

Zanatta, Felipe Augusto Scudeller; Lupinacci, Cenira Maria; Boin, Marcos Noberto

doi:10.14393/SN-v32-2020-55730

Abstract

Different studies of geomorphological science are dedicated to understanding the effect of human action on the natural dynamics of environments. Following it, this article aims to identify the effect of agriculture and conservation techniques on the dynamics of slope and bottoms of valley processes in a degraded rural area. We selected, for it, the sub-basins of Areia Dourada stream, located in the city of Marabá Paulista (SP), as objects of study, in which we used the principles of retrospective mapping, with the mapping of land use and superficial surface cover and the geomorphological features of 1963, 1979, 1997, 2011 and 2016. For the analysis, along with the mappings and field records, we used the Pearson’s Correlation Coefficient (p), together with quantified data, to evaluate the changes of the forms of relief from land use in the five mapped years. As a result, we verified: joint development of the erosive processes in different topographic compartments; feedback system between slope and bottoms of valley processes; the low efficiency of the agricultural terraces, both in the cultivated areas, but especially in the pasture areas, in order to contribute to the erosive dynamics by feeding erosive subsurface processes, while not containing the surface ones.

Keywords:
Retrospective cartography; Geomorphological; Superficial cover; Conservation techniques

Resumo

Distintos estudos da ciência geomorfológica se dedicam a compreender o efeito da ação humana na dinâmica natural dos ambientes. Nessa perspectiva, o presente artigo objetiva identificar o efeito da agricultura e das técnicas conservacionistas sobre a dinâmica dos processos de vertentes e de fundos de vale em uma área rural degradada. Para tanto, como objeto de estudo foram selecionadas subbacias do ribeirão Areia Dourada, localizadas no município de Marabá Paulista (SP), nas quais se utilizaram de princípios da cartografia retrospectiva, com o mapeamento do uso e cobertura superficial da terra e das feições geomorfológicas nos anos de 1963, 1979, 1997, 2011 e 2016. Para análise, junto aos mapeamentos e registros de campo, buscou-se com o Coeficiente de Correlação de Pearson (p) avaliar conjuntamente, com dados quantificados, as alterações das formas de relevo a partir do uso da terra nos cinco anos mapeados. Como resultado, constatou-se: desenvolvimento conjunto dos processos erosivos em distintos compartimentos topográficos; sistema de retroalimentação entre os processos de vertentes e fundos de vale; a baixa eficiência dos terraços agrícolas, tanto nas áreas de cultivo, mas, sobretudo nas áreas de pasto, de modo a contribuírem com a dinâmica erosiva ao alimentar processos erosivos de subsuperfície, ao mesmo tempo que não contém os de superfície.

Palavras-chave:
Cartografia retrospectiva; Processos erosivos; Cobertura superficial da terra; Técnicas conservacionistas

INTRODUCTION

Several studies on geomorphology aim to identify the effects of human activities on natural systems, focusing on a field dedicated to interpreting anthropic interferences as geomorphological agents, denominated anthropogeomorphology (NIR, 1983NIR, D. Man, a geomorphological agent: an Introduction to Anthropic Geomorphology. Keter Piblishing House: Jeresalem, 1983.).

For our analysis, we deemed the retrospective geomorphological mapping as a resource that allows monitoring and identifying changes in landforms over historical time. Based on this technique, authors of several studies pinpointed the effects of human activities on different environments, such as: changes in the fluvial dynamics of rivers crossing the city of São Paulo, State of São Paulo - Brazil (LUZ; RODRIGUES, 2015); mining effects (PASCHOAL, 2014); the influence of impoundments of water on morphohydrography (SIMON, 2010SIMON, A. L. H. A influência de reservatórios hidrelétricos sobre a morfohidrografia na baixa bacia do rio Piracicaba SP: contribuições ao estudo da Geomorfologia Antropogênica. Tese (Doutoramento Geografia - Organização do Espaço), Instituto de Geociência e Ciências Extadas, Universidade Estadual Paulista. São Paulo, 2010.); the influence of impoundment of water of the Paraná River and consequent changes on the regional baselevel and on the reactivation of the drainage network (QUARESMA, 2012); the influence of overgrazing, which contributes to the formation of linear erosion phenomena on lands rarely subjected to such processes (ZANATTA; LUPINACCI; BOIN, 2017aZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. Avaliação dos processos erosivos no Planalto Ocidental Paulista: um estudo de caso em busca das interações especiais. Revista Brasileira de Geomorfologia, v.18, nº 4, p. 767-782, 2017a. http://dx.doi.org/10.20502/rbg.v18i4.1029
http://dx.doi.org/10.20502/rbg.v18i4.102... ), among others.

Among processes to which soils are subjected, significant changes happen only with the replacement of native flora and fauna. In agricultural and urban areas, new soil covers are part of an environment that operates according to the dynamics predetermined by natural physical constraints - which start operating in an artificial plan whose logic, far from the natural dynamics, is determined by economic, political, and social relations.

To illustrate changes in processes to which soils are subjected, in the state of São Paulo, Brazil, Bertoni and Lombardi Neto (1990BERTONI, J; LOM BARDI-NETO, F. Conservação do solo. São Paulo: Ícone, 1990.), found that soil loss accounted for 0.004 t/ha/year in native forests. In pasture lands, the volume was 100 times higher, accounting for 0.4 t/ha/year, whereas for sugarcane cultivation it was 3,100 times higher, accounting for 12.4 t/ha/year. Considering soil characteristics, the authors identified that sandy soils correspond to the most severe soil loss in t/ha.

Among effects exerted on soils, which contribute to erosion, Wendling et al. (2005WENDLING, B.; MENDONÇA, E.S.; NEVES, J. C. L. Carbono orgânico e estabilidade de agregados de um Latossolo Vermelho sob diferentes manejos. Pesquisa Agropecuária Brasileira. Brasília, v.40, n.5, p.489-494, 2005.), found a significant reduction in the organic carbon concentration and in soil aggregate stability on soils under agricultural cultivation, when compared with values before deforestation. According to Kiehel (1979, apudWENDLING et al., 2005WENDLING, B.; MENDONÇA, E.S.; NEVES, J. C. L. Carbono orgânico e estabilidade de agregados de um Latossolo Vermelho sob diferentes manejos. Pesquisa Agropecuária Brasileira. Brasília, v.40, n.5, p.489-494, 2005.), the formation of aggregates is related to the mechanical action of roots and to the excretion of substances with cementing action; moreover, the more exposed the soil surface is, the greater the reduction in the stability of the aggregates, thus favoring surface sealing processes and inducing surface runoff and erosion.

Charlton (2008CHARLTON, R. Fundamental of fluvial geomorphology. Routledge Taylor & Francis Group: London and New York, 2008.) warns that vegetation removal consequently increases the proportion of superficial runoff of pluvial water, thus accelerating erosion-related processes. Under these conditions, higher volumes of sediments and water affect fluvial channels and change the valley forms. Abdon (2004ABDON, M. M. Os impactos ambientais no meio físico - erosão e assoreamento na bacia hidrográfica do Rio Taquari, MS, em decorrência da pecuária. Tese (Doutorado em Ciências da Engenharia Ambiental). Escola de Engenharia de São Carlos da Universidade de São Paulo, 2004. 319p.) verified that overgrazing, inadequate soil management, and misuse of certain areas have favored the development of ravines and badlands, thus increasing the amount of water and sediments that reach the main basin channel. This effect resulted in deep alluvial deposits of the Taquari river and changes in its course, in such a way to overflow and flood wide field areas, previously used for extensive livestock.

Within this context, we aimed at identifying the effect of anthropic actions on erosion processes and valley forms throughout 53 years in a degraded rural area, in a set of subbasins of the Areia Dourada stream (Figure 1), located in the municipality of Marabá Paulista, Western region of the state of São Paulo - Brazil.

To do so, we used principles of retrospective mapping for surveying data on geomorphology and land use, as well as statistical techniques for analyzing the surveyed information, seeking to identify changes and hypothesizing the influence of human activity on the intensity and dynamics of geomorphological processes.

CARTOGRAPHIC MATERIALS AND TECHNIQUES

We performed the geomorphological mapping and the mappings of land use and land cover based on topographical data of maps from Instituto Geográfico e Cartográfico do Estado de São Paulo (IGC), an institution that promotes knowledge of characteristics of the São Paulo territory, dated from 2000, in a 1:10,000 scale, 057/019, 057/20, and 058/20 sheets. Based on these maps, we vectorized contour lines with a 5-m equidistance, surveyed points, in addition to the respective altimeter values, also considering this scale as the standard value for the cartographic production.

Figure 1
Location of the study area.

For the geomorphological mapping and the mappings of land use and land cover of the five mapped years, we used different sources and photo interpretation techniques according to the characteristics of remote-sensing products (Table 1).

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Table 1
Photographs used for mapping geomorphological features and those related to land use and land cover

With materials of the years 1963, 1979, and 1997, concerning aerial surveys conducted in flight lines, we were able to work with digital stereoscopy, thus acquiring the three-dimensionality of the features. To this end, we followed the guidelines proposed by Souza and Oliveira (2012SOUZA, T. A.; REGINA, C. O. Avaliação da potencialidade de imagens tridimensionais em meio digital para o mapeamento geomorfológico. REVISTA GEONORTE. Edição especial, v.2, n.4, p.1348- 1355, 2012.) for obtaining the anaglyphs from the StereoPhoto Maker software. Conversely, for materials dated from 2010 and 2013, which consisted in orthophotographs and satellite imagery, we corrected the data in the field due to the impossibility of obtaining three-dimensionality of the features through the aforementioned method.

Noteworthy, although there are differences between scales of the aerial surveys and the scale we used in this study, we performed photo interpretation with as much zoom and detail as possible, considering that the surveyed features can be mapped and studied according to the scale and materials we used for performing the geomorphological mapping.

We mapped geomorphological features according to their spatial nature and adopted the geometry (points, line, polygons) that best adapted to their characteristics. Hence, we quantified data as regards area (hectare), quantity (number), or extent (km) according to the adopted mapping procedure (Table 2). Features calculated in hectare were transformed into percentages of the area concerning the total area of the subbasins.

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Table 2
Characteristics of geomorphological features and types of data processing

When choosing features to be mapped and the symbology to be used in geomorphological maps, we followed the principles of the French mapping system (TRICART, 1965TRICART, J. Principes et méthodes de la géomorphologie. Paris: Masson, 1965, 496p.) and the system of the International Institute for Aerial Survey and Earth Science (ITC) - which is currently called the University of Twente’s Faculty of Geo-Information Science and Earth Observation, whose aim is to develop capacity and to utilize geospatial solutions to deal with national and global problems - proposed by Verstappen and Zuidam (1975VERSTAPPEN, H. T.; ZUIDAM, R. A. System of geomorphological survey. Netherlands, Manual ITC Textbook, Vol. VII, Chapter VII, 1975.), since we sought for procedures that enabled us to recognize dominant morphogenetic processes. We adapted the methodologies to meet the studied universe, and created new symbols for typical features of the area, which did not exist in the original proposals; in addition, we assigned different colors to highlight erosion features, mapped in red, and the anthropic forms, mapped in gray (Figure 2).

To differentiate linear erosion features, according to Zanatta, Lupinacci and Boin (2017bZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. O uso de anaglifos na identificação de feições erosivas: estudo de caso em área rural degradada. In: BOIN, M.N.; MARTINS, P. C. S.; MIRANTE, M. H. P. (Org.). Geotecnologias aplicadas às questões ambientais. Tupã (SP), ed. ANAP, 1ª ed., vol.1, p.31-53, 2017b.), we considered furrows as small vertical incisions that can be repaired by simple soil preparation procedures (LAL, 1990LAL, R. Soil erosion in the tropics: principles and management. New York: McGraw- Hill, 1990.; SALOMÃO, 2012SALOMÃO, F. X. T. Controle e prevenção dos processos erosivos. In: GUERRA, A. J. T.; SILVA, A. S.; BOTELHO, R. G. M. (Org.). Erosão e conservação dos solos: conceitos, temas e aplicações. 8ª edição. Rio de Janeiro: Bertrand Brasil, 2012.; SOIL CONSERVATION SERVICE, 2006); ravines as deeper incisions, with the formation of floor surface with sidewalls (FOOKES, 2007FOOKES, P. G.; LEE, E. M.; GRIFFITHS, J. S. Engineering geomorphology: theory and practice. Dunbeath: Whittles Publishing, 2007.; KARMAN, 2008KARMAN, I. Ciclo da água: água subterrânea e sua ação geológica. In: TEIXEIRA, W.; TOLEDO, M. C. M.; FAIRCHILD, T. R.; TAIOLI, F (org.). Decifrando a Terra. São Paulo: Companhia Editora Nacional, 2008. 557p.); and badlands, whenever linear erosion reaches and exposes the groundwater (DAEE; IPT, 1989; FOOKES, 2007; SALOMÃO, 2012).

Figure 2
Symbols used in geomorphological maps.

It is worth mentioning that we could map valley forms based on photo interpretation and the analysis of orthophotographs and orbital imagery due to specificities of the erosion and depositional dynamics of the study area. Hence, in some sectors, we identified flat valley forms due to excess sediments. Nevertheless, we could not delimit alluvial plains due to the scale limits, and we mapped such areas considering the symbology suggested by Tricart (1965TRICART, J. Principes et méthodes de la géomorphologie. Paris: Masson, 1965, 496p.). Moreover, in some sectors, the intense erosion dynamics present in fluvial channels allowed us to observe the significant dissecation of valley forms due to steep margins. This exceptional dynamics of the fluvial system has allowed, after mapping the valley forms according to the proposed symbols (Figure 3), to linearly quantify these valleys (in km).

Figure 3
Identification of fluvial features in the field and photographs.

For land use and land cover, we followed the procedures and nomenclatures established by the Brazilian Institute of Geography and Statistics (IBGE, 2006), which is the main provider of data and information about Brazil, identifying the areas of: Seasonal Semideciduous Forest; reforestation; wetland vegetation; forestry; temporary crop; pasture; and dirty pasture. Since, according to our methodology, the surface soil cover has spatial dimension per occupied area, we quantified these data based on their percentage about the total study area.

With information on the mappings of land use and land cover and on geomorphology, which was quantified according to the spatial dimension, we applied the Pearson’s Correlation Coefficient (p) in the Excel program® to evaluate the intensity of correlation concerning changes in the area occupied by thematic classes of land use and land cover and geomorphological features over the 53 years, from the period between the first mapping (in 1963) to the last one (in 2016). As a result, values were distinguished with tones that vary according to the intensity of the correlation: null, when the correlation is equal to 0; weak, when it is equal to 0.1 ˫ 0.2; moderate, when it is equal to 0.3 ˫ 0.5; strong, when it is equal to 0.6 ˫ 0.8; very strong, when it is equal to 0.9; and perfect, when it is equal to 1.00; green tones were used for positive correlations, concerning the proportional increase of the features; red tones, for negative ones, concerning the inversely proportional increase of features; and white tones, concerning the null correlations. The classification of intervals was based on and adapted from Figueiredo Filho and Silva Junior (2009).

We analyzed the result of the aforementioned correlation together with mappings, field photographs, and other studies developed in Santo Anastácio river basin, in such a way to compare and provide information on correlation and to formulate hypotheses about the dynamics of the current processes from a historical perspective.

RESULTS AND DISCUSSION

The occupation of Marabá Paulista began at the basin of Areia Dourada stream, with the formation of the village of Areira Dourada in the mid-1930s, by northeastern tenant farmers who cultivated cotton (PREFEITURA DE MARABÁ PAULISTA, 2019).

From the formation of the village to the first mapped year, 1963, a period of approximately three decades, we found a reduction of about 90% of the native forest cover in the study area, i.e., 9.89% of the 4,623 ha that compose the subbasins (Figure 4).

Figure 4
Seasonal Semideciduous Forest in the subbasins of Areia Dourada stream, Marabá Paulista (SP), in 1963, 1979, 1997, 2010, and 2016.

In 1963, surface soil covers that replaced the Seasonal Semideciduous Forest were divided between temporary crops (46.62%), pasture (23.41%), and dirty pasture (18.47%). In the following period, 1979, the temporary crop area decreased to 3.63%, and pasture (69.09%) and dirty pasture (24.84%) prevailed. In 1997, pasture occupied 94.78% of the entire study area (Table 3).

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Table 3
Land use and land cover (% of occupied area) in 1963, 1979, 1997, 2010, and 2016.

These new surface soil covers resulted in effects on the landscape functioning that differ from those produced by the native forest cover. In pasture-covered areas, processes, such as linear erosion, were more frequently developed (Figure 5).

Figure 5
Deforestation and development of erosion features in the pasture area. Sector N of subbasins of Areia Dourada stream, Marabá Paulista (SP).

In the pasture area that replaces the native vegetation (Figure 6), we observe the emergence of seven linear erosions, and consequently of the better paths by which pluvial water is concentrated towards the fluvial channel, eroding the surface layer of the soil. This phenomenon strongly influences the excessive trampling cattle, thus creating favorable conditions for the channeling of pluvial water.

Rodrigues et al. (2006RODRIGUES, J. O. N.; PERUSI, M. C.; PETERLINI, G. H. C.; TIEZZI, R. O.; PISANI, R. J.; SANTANA, E. L. R. Variações texturais dos Latossolos Vermelhos do assentamento rural Antonio Conselheiro - Mirante do Paranapanema (SP). Geografia em Atos, n.6, v.1, Presidente Prudente, 2006.) clarify that this advance in pastures between the 1970s and 1990s also occurred in most of the Pontal do Paranapanema region, located in the state of São Paulo - Brazil, resulting from soil impoverishment due to its intense use and erosion, which increased the cost of cultivation and made agriculture unfeasible for small farmers. Under these conditions and devoid of alternatives, these farmers sold their land to major cattle breeders, who, according to Francisco (2011FRANCISCO, A. B. A erosão dos solos no extremo oeste paulista e seus impactos no campo e na cidade. Revista GEOMAE, Campo Mourão, v.2, n.2, p.57-68, 2011.), in an environment where erosion prevails, introduced conservation practices in the region, with the construction of agricultural terraces.

Later, in 2011, the pasture area diminished, increasing the sugarcane cultivation with the advance of sugar companies in the region by land rent. This temporary crop started occupying 18.23% of the land in 2011, decreasing to 13.43% in 2016 due to the end of lease contracts, according to reports obtained in the field, thus resuming pasture and forestry-related activities.

Soil covers that replaced the Seasonal Semideciduous Forest throughout these five years provided an expressive and growing increase in erosion forms in number (furrows and ravines) and affected area (features that indicate laminar erosion and badlands) in the 53 analyzed years, even when employing conservation techniques from 1979 onwards, which did not mitigate erosion effects in the area in the following years (Figure 6).

Figure 6
Erosion features and techniques for conservation and containment of erosion processes in 1963, 1979, 1997, 2011 and 2016.

Stein, Ponçano and Saad (2003STEIN, D. P.; PONÇANO, W. L.; SAAD, A. R. Erosão na bacia do Rio Santo Anastácio, Oeste do estado de São Paulo, Brasil. Revista Geociências. v.22, n.2, p.143-161, 2003.) also found this relationship between conservation techniques and erosion processes in the Santo Anastácio river basin. According to the authors, larger water infiltrations provoked by agricultural terraces led to an increase in recharges of groundwater, which previously existed within native forests. Such recharges, within the area of the Adamantina Formation, a geological formation in the Bauru basin, located in the western region of the state of São Paulo - Brazil, result in upwelling of water table in slopes, with the flow of water directed to territories already fragile and poorly protected by the continuous and intense land use, which drives the development of erosion phenomena.

According to the obtained information, we observed the proportional increase in erosion features, in addition to the greater use of agricultural terraces in the study area, as well as the extent of upwellings of water table due to abrupt break slopes, reflecting the significant changes in valley forms that occurred especially from 1997 onwards, and where the use of agricultural terraces became the standard of cultivated areas (Figure 7).

Figure 7
Agricultural terraces, upwellings of water table, and fluvial channel features.

In 1997, when compared with previous years (1963 and 1979), channels with flat valley forms decreased as terraces and alluvial plain increased due to alluvial deposits of the channels. In other sectors, we perceived an increase in V-shaped valley forms, indicating the river incision dynamism, which is probably caused by the increase in break slopes with an upwelling of water table. These upwellings of water started favoring the emergence and development of new fluvial channels in slope concaves.

In 2011, there was a reduction in V-shaped valley forms and an increase in river channels with flat valley form and terraces and alluvial plain (Figure 7), indicating the constant alluvial deposits of river courses due to intense erosion activity in the slopes (Figure 6). Moreover, in the same year, we found 63.6% of fluvial channels with undermining of margins due to the increase in the amount of water and sediments deriving from the slopes.

In the five-year interval, from 2011 to 2016, we perceived no changes in fluvial features. This finding is probably related to the short time between the evaluated years, in such a way we cannot verify significant changes in the valley forms considering the increase of processes in the slopes.

After evaluating the correlation between data on geomorphology and land use, we verified the inefficiency of conservation techniques in containing erosion processes, the influence of pastures on stimulating such processes, and the proportional increase between erosion features (Table 4).

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Table 4
Pearson’s Correlation Coefficient (PCC) concerning the variables of land use and geomorphological features throughout the years 1963, 1979 and 1997, and 2011 and 2016.

Seasonal Semideciduous Forest, which reduced throughout the analyzed period, presented a negative correlation with erosion forms, having perfect correlation with features that indicate laminar erosion; a very strong correlation with the formation of badlands; and strong correlation with furrows and ravines. This correlation is partly justified by the increase in erosion features in areas that were previously occupied by original vegetation (Figure 6). Nevertheless, it is also because of the ongoing decrease in this vegetation and the increase in erosion features, which cannot be understood as the emergence of erosion only in places where deforestation has occurred. Increase in erosion features virtually occurs in the entire study area, under several conditions of land use.

Pasture, the predominant soil cover in the study area, presented a perfect positive correlation with features that indicate laminar erosion; a positive strong correlation with furrows; a moderate positive correlation with ravines; and a positive very strong correlation with badlands.

Regarding temporary crops, the correlation was negative, being strong with badlands and very strong with features that indicate laminar erosion. In the field, we noted features that indicated laminar erosion and the formation of furrows in areas for sugarcane cultivation. We could not map these features due to the constant corrections of agricultural terraces (Figure 8).

Figure 8
Features of laminar erosion and furrows in soils of sugarcane cultivation (2013). Photographs were taken after rainy events.

According to our analysis, the development of erosion processes jointly occurs, in such a way that erosion features showed a positive correlation with each other: features that indicate laminar erosion had a strong correlation with furrows and ravines, and a perfect correlation with badlands. Furrows had a very strong correlation with ravines and badlands, and the correlation between ravines and badlands was strong. These correlations indicate that evolution in erosion forms is interconnected with other processes occurring in the same subbasin (Figure 9).

Figure 9
Evolution of erosion forms at the W subbasin, affected by the formation of badlands from 1997 onwards.

There is a connection between erosion forms (Figure 9). In 1963, several furrows were directed to the slope concave. In 1979, the formation of a ravine was registered in this slope concave, thus increasing the number of furrows and features that indicate laminar erosion in other slopes. In 1997, the aforementioned ravine developed into a badland, and other ravines emerged on its margins, to which furrows from higher sectors converge. In 2011 and 2016, this dynamics was intensified, with ravines migrating upstream and dozens of ravines emerging in lower slopes, with a greater number of furrows and features that indicate laminar erosion.

As for conservation techniques, the correlation indicated the low efficiency of terraces and contention basins in soil conservation, since they present a positive correlation with all erosion forms: very strong with furrows; perfect with ravines; and strong with badlands.

Furthermore, we observed that changes in valley forms are also related to processes occurring in slopes and to conservation techniques (Figure 4). Erosion forms presented a negative correlation with V-shaped and flat valley forms, and a positive correlation from very strong to perfect with terraces and alluvial plain. Erosion processes in slopes increase the flow of water and sediments towards valley forms, in such a way to expand sedimentation areas, resulting in the positive correlation with terraces and alluvial plain, and also in the reduction of channels with V-shaped and flat valley forms, where there was a negative correlation with all erosion forms (Figure 10).

As we highlighted in Figure 10, the increase in erosion features between 1979 and 2011 enabled greater sedimentation of valley forms, thus expanding the deposition area. Moreover, in this period, we observed that this excessive sedimentation provoked changes in the course of the main channel with undermining of margins. This process, upon reaching the base of the slope, has favored its collapse, in such a way dozens of small ravines emerged, which are developed by regressive erosion. Stein, Ponçano and Saad (2003STEIN, D. P.; PONÇANO, W. L.; SAAD, A. R. Erosão na bacia do Rio Santo Anastácio, Oeste do estado de São Paulo, Brasil. Revista Geociências. v.22, n.2, p.143-161, 2003.) also pinpointed this relationship in a study on Santo Anastácio river basin and on Areia Dourada stream.

Figure 10
Erosion processes in slopes with the consequent undermining of margins and formation of terraces and alluvial plain in channels with flat valley form.

Upwellings of water table in break slopes, when jointly verified with geomorphological mappings especially from 1979 and 1997, gave rise to small fluvial channels downstream with V-shaped valley forms. In 2011, the length of these channels decreased due to the construction of reservoirs, which limited the flow until the upstream impoundment of water. We did not verify downstream runoff (Figure 11).

Figure 11
Tributaries of the main channel before (1997) and after (2011 and 2016) the impoundment of water and formation of reservoirs. (1) Absence of runoff downstream upwelling of water table in sector NW; (2) Absence of runoff downstream upwelling of water table in sector W.

Thus, the negative correlation between abrupt break slopes with an upwelling of water table and V-shaped valley forms is disregarded when evaluated together with mappings and records of the field, since conservation techniques and reservoirs were variables that mostly interfered in valley forms. The increase in water infiltration due to conservation techniques and the impoundment of water transformed channels with V-shaped valley forms into pluvial channels (Figure 8).

Regarding the basin with the major process of formation of badlands (Figure 12), we found changes in erosion dynamics after the impoundment of water with reservoir formation, erosion control, and contention basins, hence altering the location and development of ravines when compared with previous years. Thus, we recorded the emergence of dozens of ravines in lower slopes from 2011 onwards.

We mapped another badland in the southeast sector of the study area, whose runoff is directed to a former rural road (Figure 13). In this area, until 2011, the flow of water at the base of erosion was absorbed by the soil, whereas in 2016 the surface runoff started affecting the river channel, which is also affected by the process of formation of badlands, downstream the impoundment of water. This increase in the flow of water at the base of erosion occurs due to greater infiltration of water provided by contention basins and agricultural terraces in the slopes.

Figure 12
Changes in the pattern of formation and development of ravines after impoundment of water of badlands.

Figure 13
Influence of agricultural terraces on the flow of water in the channel of anthropogenic origin, resulting from the process of formation of badlands affecting the rural road. (1) Surface runoff at the base of badland in 2012; (2) Surface runoff at the base of badland in 2016.

In the northernmost sector of the study area (Figure 14), agricultural terraces provided a higher volume of abrupt break slopes with upwelling of water table within sectors of land overgrazing. Under these circumstances, of excessive use and greater flow of water deriving from break slopes with upwelling of water table, we noted the formation of badlands in 2011 and in 2016.

Figure 14
Formation of badlands downstream break slopes with upwelling of water table. Photographs 1, 2, and 3: badlands in sector NNW of the study area.

Overall, we can state that our data demonstrate the existence of intense use in virtually all slopes, at the expense of reforestation and crops that provide improvements in the structure of sandy soil and greater protection against the erosion effect of the rains, thus favoring the formation and development of erosion processes. Therefore, we can predict that, if the current conditions remain, erosion phenomena and continuous soil loss tend to increase, even when employing different conservation techniques.

FINAL CONSIDERATIONS

Through the applied techniques, we identified the erosion and depositional dynamics of the study area, in addition to verifying the connection between erosion forms in the several topographic elements of the area. These erosion forms provoked changes in valley forms, with the undermining of river margins, promoting the collapse of lower slopes and the emergence of many ravines. Such ravines increase the flow of water and sediments in valley forms, establishing an erosion-alluvial deposits cycle that provides feedback.

Pastures consisted in catalysts for many of the identified linear processes. Excessive trampling cattle generated the compaction of the surface layer, where furrows are developed. These furrows are inserted in the erosion dynamics previously mentioned

Conservation techniques have contributed to the development of erosion processes through recharges of groundwater, which, associated with intense land use, favored the subsurface processes characteristic of badlands; at the same time, they did not reduce surface processes. As for impoundments of water in channels with the formation of badlands, such impoundments changed the erosion development by the emergence of dozens of small ravines in every lower slope, which were no longer restricted to slope concaves, as recorded in periods before the impoundment of water.

In general, by retrospective mapping and Pearson’s Correlation Coefficient, we can hypothesize the influence of land use and land cover on changes in geomorphological features identified in the study area throughout 53 years. Such findings may contribute to the understanding of erosion dynamics, a relevant issue for a possible recovery of subbasins of the Areia Dourada stream.

ACKNOWLEDGMENTS

To Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), for financing the first month of research, from April to May 2015, and to Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP), for funding the PhD project, process no. 2015/00875-2, from May 2015 to April 2018.

To the opinion givers, for the contributions to improving this article.

REFERENCES

ABDON, M. M. Os impactos ambientais no meio físico - erosão e assoreamento na bacia hidrográfica do Rio Taquari, MS, em decorrência da pecuária. Tese (Doutorado em Ciências da Engenharia Ambiental). Escola de Engenharia de São Carlos da Universidade de São Paulo, 2004. 319p.
BERTONI, J; LOM BARDI-NETO, F. Conservação do solo. São Paulo: Ícone, 1990.
BORGES, P. A evolução dos processos erosivos na bacia hidrográfica do ribeirão Alam Grei (SP): uma contribuição ao planejamento ambiental. Dissertação (Mestrado em Geografia - Organização do Espaço). Instituto de Geociência e Ciências Exatas, Universidade Estadual Paulista, 2009, p.?
CARVALHO, W. A. (coord.). Levantamento semidetalhado dos solos da bacia do rio Santo Anastácio-SP. Presidente Prudente, São Paulo: FCT- UNESP, 1997. v.1 e v.2.
CHARLTON, R. Fundamental of fluvial geomorphology. Routledge Taylor & Francis Group: London and New York, 2008.
DEPARTAMENTO DE ÁGUAS E ENERGIA ELÉTRICA (DAEE); INSTITUTO DE PESQUISAS TECNOLÓGICAS (IPT). Controle de erosão: bases conceituais e técnicas; diretrizes para o planejamento urbano e regional; orientações para o controle de boçorocas urbanas. São Paulo: DAEE/IPT, 1989.
FRANCISCO, A. B. A erosão dos solos no extremo oeste paulista e seus impactos no campo e na cidade. Revista GEOMAE, Campo Mourão, v.2, n.2, p.57-68, 2011.
FIGUEIREDO FILHO, D. B.; SILVA JUNIOR, J. A. Desvendando os Mistérios do Coeficiente de Correlação de Pearson ®*. Revista Política Hoje, Vol. 18, n.1, p. 115-146, 2009.
FOOKES, P. G.; LEE, E. M.; GRIFFITHS, J. S. Engineering geomorphology: theory and practice. Dunbeath: Whittles Publishing, 2007.
INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA (IBGE). Manual Técnico de Uso da Terra. 3ª edição. Rio de Janeiro: IBGE, 2006.
KARMAN, I. Ciclo da água: água subterrânea e sua ação geológica. In: TEIXEIRA, W.; TOLEDO, M. C. M.; FAIRCHILD, T. R.; TAIOLI, F (org.). Decifrando a Terra. São Paulo: Companhia Editora Nacional, 2008. 557p.
LAL, R. Soil erosion in the tropics: principles and management. New York: McGraw- Hill, 1990.
LUZ, R.; RODRIGUES, C. Anthropogenic changes urbanised hidromorphological systems in a humid tropical environment River Pinheiros, São Paulo, Brasil.. Zeitschrift fur Geomorphologie. Supplementband, v. 59, p. 109, 2015. http://dx.doi.org/10.1127/zfg_suppl/2015/S59207
» http://dx.doi.org/10.1127/zfg_suppl/2015/S59207
NIR, D. Man, a geomorphological agent: an Introduction to Anthropic Geomorphology. Keter Piblishing House: Jeresalem, 1983.
PASCHOLA, L. G. Estudo dos efeitos da criação de morfologias antropogênicas em áreas de mineração. Tese (Mestrado em Geografia - Organização do Espaço). Instituto de Geociência e Ciências Exatas, Universidade Estadual Paulista, 2014, p.?
PREFEITURA DE MARABÁ PAULISTA. Informações sobre a história da cidade. Disponível em: <https://marabapaulista.sp.gov.br/cidade>. Acesso em 08 de dezembro de 2019.
» https://marabapaulista.sp.gov.br/cidade
QUARESMA, C. C. Reativação da rede de drenagem e processos erosivos na bacia do rio Santo Anastácio - SP/BRASIL: contribuições à geomorfologia antrópica e ao entendimento das organizações espaciais. Tese (Doutorado em Geografia), Universidade Estadual de Campinas.
RODRIGUES, J. O. N.; PERUSI, M. C.; PETERLINI, G. H. C.; TIEZZI, R. O.; PISANI, R. J.; SANTANA, E. L. R. Variações texturais dos Latossolos Vermelhos do assentamento rural Antonio Conselheiro - Mirante do Paranapanema (SP). Geografia em Atos, n.6, v.1, Presidente Prudente, 2006.
SALOMÃO, F. X. T. Controle e prevenção dos processos erosivos. In: GUERRA, A. J. T.; SILVA, A. S.; BOTELHO, R. G. M. (Org.). Erosão e conservação dos solos: conceitos, temas e aplicações. 8ª edição. Rio de Janeiro: Bertrand Brasil, 2012.
SIMON, A. L. H. A influência de reservatórios hidrelétricos sobre a morfohidrografia na baixa bacia do rio Piracicaba SP: contribuições ao estudo da Geomorfologia Antropogênica. Tese (Doutoramento Geografia - Organização do Espaço), Instituto de Geociência e Ciências Extadas, Universidade Estadual Paulista. São Paulo, 2010.
SOIL SURVEY STAFF. Soil Survey Manual. USDA: Soil Conservation Service,Agricultural Handbook. Nº 18, U. S. Gov. Print: Office, Wahsington, D. C. 1993.
SOUZA, T. A.; REGINA, C. O. Avaliação da potencialidade de imagens tridimensionais em meio digital para o mapeamento geomorfológico. REVISTA GEONORTE. Edição especial, v.2, n.4, p.1348- 1355, 2012.
STEIN, D. P.; PONÇANO, W. L.; SAAD, A. R. Erosão na bacia do Rio Santo Anastácio, Oeste do estado de São Paulo, Brasil. Revista Geociências. v.22, n.2, p.143-161, 2003.
TRICART, J. Principes et méthodes de la géomorphologie. Paris: Masson, 1965, 496p.
VERSTAPPEN, H. T.; ZUIDAM, R. A. System of geomorphological survey. Netherlands, Manual ITC Textbook, Vol. VII, Chapter VII, 1975.
WENDLING, B.; MENDONÇA, E.S.; NEVES, J. C. L. Carbono orgânico e estabilidade de agregados de um Latossolo Vermelho sob diferentes manejos. Pesquisa Agropecuária Brasileira. Brasília, v.40, n.5, p.489-494, 2005.
ZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. Avaliação dos processos erosivos no Planalto Ocidental Paulista: um estudo de caso em busca das interações especiais. Revista Brasileira de Geomorfologia, v.18, nº 4, p. 767-782, 2017a. http://dx.doi.org/10.20502/rbg.v18i4.1029
» http://dx.doi.org/10.20502/rbg.v18i4.1029
ZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. O uso de anaglifos na identificação de feições erosivas: estudo de caso em área rural degradada. In: BOIN, M.N.; MARTINS, P. C. S.; MIRANTE, M. H. P. (Org.). Geotecnologias aplicadas às questões ambientais. Tupã (SP), ed. ANAP, 1ª ed., vol.1, p.31-53, 2017b.

Publication Dates

Publication in this collection
24 Jan 2022
Date of issue
2020

History

Received
26 June 2020
Accepted
26 June 2020

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

[1] ABDON, M. M. Os impactos ambientais no meio físico - erosão e assoreamento na bacia hidrográfica do Rio Taquari, MS, em decorrência da pecuária. Tese (Doutorado em Ciências da Engenharia Ambiental). Escola de Engenharia de São Carlos da Universidade de São Paulo, 2004. 319p.

[2] BERTONI, J; LOM BARDI-NETO, F. Conservação do solo. São Paulo: Ícone, 1990.

[3] BORGES, P. A evolução dos processos erosivos na bacia hidrográfica do ribeirão Alam Grei (SP): uma contribuição ao planejamento ambiental. Dissertação (Mestrado em Geografia - Organização do Espaço). Instituto de Geociência e Ciências Exatas, Universidade Estadual Paulista, 2009, p.?

[4] CARVALHO, W. A. (coord.). Levantamento semidetalhado dos solos da bacia do rio Santo Anastácio-SP. Presidente Prudente, São Paulo: FCT- UNESP, 1997. v.1 e v.2.

[5] CHARLTON, R. Fundamental of fluvial geomorphology. Routledge Taylor & Francis Group: London and New York, 2008.

[6] DEPARTAMENTO DE ÁGUAS E ENERGIA ELÉTRICA (DAEE); INSTITUTO DE PESQUISAS TECNOLÓGICAS (IPT). Controle de erosão: bases conceituais e técnicas; diretrizes para o planejamento urbano e regional; orientações para o controle de boçorocas urbanas. São Paulo: DAEE/IPT, 1989.

[7] FRANCISCO, A. B. A erosão dos solos no extremo oeste paulista e seus impactos no campo e na cidade. Revista GEOMAE, Campo Mourão, v.2, n.2, p.57-68, 2011.

[8] FIGUEIREDO FILHO, D. B.; SILVA JUNIOR, J. A. Desvendando os Mistérios do Coeficiente de Correlação de Pearson ®*. Revista Política Hoje, Vol. 18, n.1, p. 115-146, 2009.

[9] FOOKES, P. G.; LEE, E. M.; GRIFFITHS, J. S. Engineering geomorphology: theory and practice. Dunbeath: Whittles Publishing, 2007.

[10] INSTITUTO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA (IBGE). Manual Técnico de Uso da Terra. 3ª edição. Rio de Janeiro: IBGE, 2006.

[11] KARMAN, I. Ciclo da água: água subterrânea e sua ação geológica. In: TEIXEIRA, W.; TOLEDO, M. C. M.; FAIRCHILD, T. R.; TAIOLI, F (org.). Decifrando a Terra. São Paulo: Companhia Editora Nacional, 2008. 557p.

[12] LAL, R. Soil erosion in the tropics: principles and management. New York: McGraw- Hill, 1990.

[13] LUZ, R.; RODRIGUES, C. Anthropogenic changes urbanised hidromorphological systems in a humid tropical environment River Pinheiros, São Paulo, Brasil.. Zeitschrift fur Geomorphologie. Supplementband, v. 59, p. 109, 2015. http://dx.doi.org/10.1127/zfg_suppl/2015/S59207
» http://dx.doi.org/10.1127/zfg_suppl/2015/S59207

[14] NIR, D. Man, a geomorphological agent: an Introduction to Anthropic Geomorphology. Keter Piblishing House: Jeresalem, 1983.

[15] PASCHOLA, L. G. Estudo dos efeitos da criação de morfologias antropogênicas em áreas de mineração. Tese (Mestrado em Geografia - Organização do Espaço). Instituto de Geociência e Ciências Exatas, Universidade Estadual Paulista, 2014, p.?

[16] PREFEITURA DE MARABÁ PAULISTA. Informações sobre a história da cidade. Disponível em: <https://marabapaulista.sp.gov.br/cidade>. Acesso em 08 de dezembro de 2019.
» https://marabapaulista.sp.gov.br/cidade

[17] QUARESMA, C. C. Reativação da rede de drenagem e processos erosivos na bacia do rio Santo Anastácio - SP/BRASIL: contribuições à geomorfologia antrópica e ao entendimento das organizações espaciais. Tese (Doutorado em Geografia), Universidade Estadual de Campinas.

[18] RODRIGUES, J. O. N.; PERUSI, M. C.; PETERLINI, G. H. C.; TIEZZI, R. O.; PISANI, R. J.; SANTANA, E. L. R. Variações texturais dos Latossolos Vermelhos do assentamento rural Antonio Conselheiro - Mirante do Paranapanema (SP). Geografia em Atos, n.6, v.1, Presidente Prudente, 2006.

[19] SALOMÃO, F. X. T. Controle e prevenção dos processos erosivos. In: GUERRA, A. J. T.; SILVA, A. S.; BOTELHO, R. G. M. (Org.). Erosão e conservação dos solos: conceitos, temas e aplicações. 8ª edição. Rio de Janeiro: Bertrand Brasil, 2012.

[20] SIMON, A. L. H. A influência de reservatórios hidrelétricos sobre a morfohidrografia na baixa bacia do rio Piracicaba SP: contribuições ao estudo da Geomorfologia Antropogênica. Tese (Doutoramento Geografia - Organização do Espaço), Instituto de Geociência e Ciências Extadas, Universidade Estadual Paulista. São Paulo, 2010.

[21] SOIL SURVEY STAFF. Soil Survey Manual. USDA: Soil Conservation Service,Agricultural Handbook. Nº 18, U. S. Gov. Print: Office, Wahsington, D. C. 1993.

[22] SOUZA, T. A.; REGINA, C. O. Avaliação da potencialidade de imagens tridimensionais em meio digital para o mapeamento geomorfológico. REVISTA GEONORTE. Edição especial, v.2, n.4, p.1348- 1355, 2012.

[23] STEIN, D. P.; PONÇANO, W. L.; SAAD, A. R. Erosão na bacia do Rio Santo Anastácio, Oeste do estado de São Paulo, Brasil. Revista Geociências. v.22, n.2, p.143-161, 2003.

[24] TRICART, J. Principes et méthodes de la géomorphologie. Paris: Masson, 1965, 496p.

[25] VERSTAPPEN, H. T.; ZUIDAM, R. A. System of geomorphological survey. Netherlands, Manual ITC Textbook, Vol. VII, Chapter VII, 1975.

[26] WENDLING, B.; MENDONÇA, E.S.; NEVES, J. C. L. Carbono orgânico e estabilidade de agregados de um Latossolo Vermelho sob diferentes manejos. Pesquisa Agropecuária Brasileira. Brasília, v.40, n.5, p.489-494, 2005.

[27] ZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. Avaliação dos processos erosivos no Planalto Ocidental Paulista: um estudo de caso em busca das interações especiais. Revista Brasileira de Geomorfologia, v.18, nº 4, p. 767-782, 2017a. http://dx.doi.org/10.20502/rbg.v18i4.1029
» http://dx.doi.org/10.20502/rbg.v18i4.1029

[28] ZANATTA, F. A. S.; LUPINACCI, C. M.; BOIN, M.N. O uso de anaglifos na identificação de feições erosivas: estudo de caso em área rural degradada. In: BOIN, M.N.; MARTINS, P. C. S.; MIRANTE, M. H. P. (Org.). Geotecnologias aplicadas às questões ambientais. Tupã (SP), ed. ANAP, 1ª ed., vol.1, p.31-53, 2017b.

Source	Year	Scale/Resolution	Photographs in the catalog	Type of mapping
State of São Paulo	1963	1: 25,000	FX91A-2857 and 2858; FX92-2871 and 2873; and FX93-2921 and 2922.	Photo interpretation in digital stereoscopy.
Terrafoto S.A.	1979	1: 25,000	FX91A-2857 and 2858; FX92-2871 and 2873; and FX93-2921 and 2922	Photo interpretation in digital stereoscopy.
Aerial surveys conducted in Presidente Venceslau (municipality of São Paulo, state of São Paulo - Brazil) and surrounding areas	1997	1:35,000	07/5884; 07/5885 and 07/8856.	Photo interpretation in digital stereoscopy.
Empresa de Planejamento Metropolitano S.A.	2010	Resolution of 0.45 m	SF_22_YB_I_2_ NE and SE; and SF_22_YB_II_1_NO and SO.	Photo interpretation and correction of data in the field.
Google Earth - Quickbird satellite	2013	Resolution of 0.6 m	No information.	Photo interpretation and correction of data in the field.

Spatial nature	Feature	Geometry	Size estimation
Area	Features that indicate laminar erosion	Polygon	Hectare (ha)
	Terrace and alluvial plain
	Agricultural terrace
	Reservoir
Quantity	Furrows	Line	Total number of mapped features
	Ravine
	Erosion control features
	Contention Basins
Extent	Fluvial channel with flat valley form	Line	Total kilometers (Km) of extent
	Fluvial channel with V-shaped valley form
	Fluvial channel with undermining of margins
	Abrupt break slope
	Abrupt break slope with upwelling of water table

Land use and land cover	1963	1979	1997	2010	2016
Seasonal Semideciduous Forest	9.89	0.88	0.71	0.72	0.70
Reforestation	0.00	0.00	0.70	1.23	1.20
Wetland vegetation	0.70	0.60	0.94	1.61	1.57
Temporary crop	46.62	3.63	0.80	18.32	13.45
Forestry	0.91	0.96	0.08	0.11	4.24
Pasture	23.41	69.09	94.78	72.92	74.30
Dirty pasture	18.47	24.84	1.99	5.09	4.54

	SSF	RF	RS	TC	P	DP	LE	S	R	B	VVF	FVF	TAP	CUM	ABS	ABSW	AT
LE
S
R
B
VVF
FVF
TAP
CUM
ABS
ABSW
AT
RS
CE
CB

Caption:
Correlation intensity	Positive	Negative
Perfect
Very strong
Strong
Moderate
Weak
Null