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Analysis of quantitative methods for geodiversity in Chapada Diamantina, Bahia, Brazil

Abstract:

The concept of geodiversity has been developed by geoscientists since 1990 in different lines of research such as territorial and patrimonial planning, tourism and the dissemination of knowledge. However, little progress has been made in mapping and quantifying geodiversity. Thus, there are still gaps about the functionality of these graphics products. In order to contribute to these discussions, the aim of this research was to evaluate geodiversity quantification models in Chapada Diamantina National Park and municipality of Morro do Chapéu. The methods Serrano and Ruiz - Flaño and Pereira et al. were chosen for comparison. After choosing the criteria to compare as the choice of variables pertaining to each method, data processing was performed in a geographic information system. Maps with geodiversity indexes and frequency charts were generated. Finally, these products were analyzed using statistical methods and evaluated in the field. In both proposals for quantifying geodiversity, methodological limitations were found, which interfere with the purpose for which the index was created.

Keywords:
geodiversity index; models in the Geosciences; landscape quantification

1. Introduction

Changes in environmental systems caused by interventions in the primitive landscape bring damage to the ecological balance and the maintenance of life. In this context, the academic environment began to develop and disseminate concepts that supported the development of methods focused on environmental issues such as the preservation of the natural heritage. Environmental issues, especially those related to the preservation of biodiversity, have gained importance in the media and government agencies since the RIO - 92.

Despite the greater popularization of the term biodiversity, which for decades has had a theoretical-methodological framework already systematized in the scientific community, the geodiversity neologism was also designated. The concept of geodiversity was initially thought of as analogous to that of biodiversity (Serrano and Ruiz-Flaño 2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ; Carcavilla et al. 2008Carcavilla, L., Durán, J. J., and López-Martínez, J., 2008. Geodiversidad: concepto y relación con el patrimonio geológico.Geo-Temas, 10(2008), pp.1299-1303.; Gray 2013Gray, M., 2013. Geodiversity - Valuing and Conserving Abiotic Nature. New York: John Wiley and Sons.). It can be defined as: The natural range (diversity) of geological (rocks, minerals, fossils), geomorphological (landforms, topography, physical processes), soil and hydrological features. It includes their assemblages, structures, systems and contributions to landscapes (Gray 2013Gray, M., 2013. Geodiversity - Valuing and Conserving Abiotic Nature. New York: John Wiley and Sons.). There are other definitions of geodiversity such as Sharples (1995Sharples, C., 1995. Geoconservation in forest management-principles and procedures.Tasforests-Hobart, pp. 37-50.); Johansson et al. (1999Johansson, C. E., Andersen, S., & Alapassi, M., 1999. Geodiversity in the Nordic countries.ProGeo News, pp. 1-3.); Stanley (2000Stanley, M., 2000. Geodiversity. Earth heritage, pp. 15-18.); Nieto (2001Nieto, L. M., 2001. Geodiversidad: propuesta de una definición integradora.Boletín Geológico y minero, 112(2), pp. 3-12.); Kozlowski (2004Kozlowski, S., 2004. Geodiversity. The coneept and scope of geodiversity. - In: Polish geological review (Przeglad geologiczny), 8(2), pp. 833-839.); Serrano and Flaño (2007)Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. . Although there are disagreements about the concept, geological, geomorphological elements and soils are common to all and are the most relevant structural elements of the landscape (Forte 2018Forte, J. P., Brilha, J., Pereira, D. I., and Nolasco, M. (2018). Kernel density applied to the quantitative assessment of geodiversity.Geoheritage , 10(2), pp. 205-217.).

On the one hand, qualitative methods were developed for the inventorying and valuation of geomorphological and geological heritage such as those of Rivas et al. (1997Rivas, V., Rix, K., Frances, E., Cendrero, A., and Brunsden, D., 1997. Geomorphological indicators for environmental impact assessment: consumable and non-consumable geomorphological resources. Geomorphology , 18(3-4), pp. 169-182.); Panizza (2001Panizza, M. (2001). Geomorphosites: concepts, methods and examples of geomorphological survey.Chinese science bulletin, 46(1), pp. 4-5. ); Bruschi and Cendrero (2005Bruschi, V. M., and Cendrero, A., 2005. Geosite evaluation: can we measure intangible values.Il Quaternario, 18(1), pp.293-306.); Pereira et al. (2007Pereira, P., Pereira, D., and Caetano Alves, M. I., 2007. Geomorphosite assessment in Montesinho natural park (Portugal).Geographica helvetica, 62(3), pp. 159-168.); Reynard (2007Reynard, E., Fontana, G., Kozlik, L., and Scapozza, C., 2007. A method for assessing scientific and additional values of geomorphosites.Geographica Helvetica, 62(3), pp. 148-158.); Zouros (2007Zouros, N. C., 2007. Geomorphosite assessment and management in protected areas of Greece Case study of the Lesvos island-coastal geomorphosites.Geographica Helvetica , 62(3), pp. 169-180.) and Garcia - Cortes and Urqui (2009)Garcia-Cortés, A., and Úrqui, L. C., 2009. Proposta para la atualización metodológica del inventário español de lugares de interés geológico (IELIG).Espanha: Instituto Geológico y Minero de España.. These proposals have as a common characteristic, not encompassing different levels of coverage, but mainly of abiotic-geological type (Zwolinski 2018Zwoliński, Z., Najwer, A., and Giardino, M., 2018. Methods for assessing geodiversity. InGeoheritage , pp. 27-52. ).

On the other hand, there are lines of research that aim to evaluate geodiversity in an integrated manner using direct and indirect methods (Manosso and Ondicol 2012Manosso, F. C., and Ondicol, R. P., 2012. Geodiversidade: considerações sobre quantificação e avaliação da distribuição espacial.Anuário do Instituto de Geociências, 35(1), pp. 90-100.), quantitative or qualitative-quantitative, (Zwolinski 2018Zwoliński, Z., Najwer, A., and Giardino, M., 2018. Methods for assessing geodiversity. InGeoheritage , pp. 27-52. ) whose main researchers are: Xavier da Silva (2001)Xavier da Silva, J., Persson, V. G., Lorini, M. L., Bergamo, R. B. A., Ribeiro, M. F., Costa, A. J. S. T., ... and Abdo, O. E., 2001. Índices de geodiversidade: aplicações de SGI em estudos de biodiversidade. Conservação da biodiversidade em ecossistemas tropicais: avanços conceituais e revisão novas metodologias de avaliação e monitoramento. Rio de Janeiro, Vozes, pp. 299-316.; Kozlowski (2004Kozlowski, S., 2004. Geodiversity. The coneept and scope of geodiversity. - In: Polish geological review (Przeglad geologiczny), 8(2), pp. 833-839.); Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ); Carcavilla et al. (2008Carcavilla, L., Durán, J. J., and López-Martínez, J., 2008. Geodiversidad: concepto y relación con el patrimonio geológico.Geo-Temas, 10(2008), pp.1299-1303.); Benito-Calvo et al. (2009Benito-Calvo, A., Pérez-González, A., Magri, O., & Meza, P., 2009. Assessing regional geodiversity: The Iberian Peninsula.Earth surface processes and landforms, 34(10), pp.1433-1445.); Zwolinski (2009)Zwolinski, Z., 2009. The routine of landform geodiversity map design for the Polish Carpathian Mts. Landform Analysis, pp. 77-85.; Hjort and Luoto (2010Hjort, J., and Luoto, M. (2010). Geodiversity of high-latitude landscapes in northern Finland.Geomorphology, 115(1-2), pp. 109-116., 2012Hjort, J; luoto, M., 2012. Can geodiversity be predicted from space? Geomorphology , v. 153, pp. 74-80.); Ruban (2010Ruban, D. A., 2010. Quantification of geodiversity and its loss. Proceedings of the Geologists’ Association, 121(3), pp. 326-333.); Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.); Silva et al. (2015)Silva, J. P., Rodrigues, C., and Pereira, D. I., 2015. Mapping and analysis of geodiversity indices in the Xingu River basin, Amazonia, Brazil. Geoheritage , 7(4), pp. 337-350.; Melelli (2014Melelli, L., 2014. Geodiversity: a new quantitative index for natural protected areas enhancement.Geojournal of tourism and geosites, 1(13), pp. 27-37.); Manosso and Nobrega (2016)Manosso, F.C. and de Nóbrega, M.T., 2016. Calculation of Geodiversity from Landscape Units of the Cadeado Range Region in Paraná, Brazil. Geoheritage , 8(3) pp. 189-199.; Argyriou et al. (2016Argyriou, A. V., Sarris, A., & Teeuw, R. M., 2016. Using geoinformatics and geomorphometrics to quantify the geodiversity of Crete, Greece.International journal of applied earth observation and geoinformation, pp. 47-59. ); Araújo and Pereira (2018)Araujo, A. M., and Pereira, D. Í., 2018. A new methodological contribution for the geodiversity assessment: applicability to Ceará State (Brazil).Geoheritage, 10(4), pp.591-605.; Santos et al. (2019)Santos, D. S., Mansur, K. L., de Arruda Jr, E. R., Dantas, M. E., & Shinzato, E., 2019. Geodiversity mapping and relationship with vegetation: A regional-scale application in SE Brazil. Geoheritage , 11(2), pp. 399-415. and Forte (2018Forte, J. P., Brilha, J., Pereira, D. I., and Nolasco, M. (2018). Kernel density applied to the quantitative assessment of geodiversity.Geoheritage , 10(2), pp. 205-217.). In practice, the methods of geodiversity assessment and quantification propose new tools for landscape analysis, help in decision-making on topics such as conservation of the abiotic environment, ecosystem services, territorial management, and the study of the relationships between abiotic and biotic elements.

Thus, although the number of works on geodiversity quantification has been intensifying (Ruchkys et al. 2017Ruchkys, Ú., Mansur, K. L., & Bento, L. C. M., 2017. A Historical and Statistical Analysis of the Brazilian Academic Production, on Master’s and PhD Level, on the Following Subjects: Geodiversity, Geological Heritage, Geotourism, Geoconservation and Geoparks.Anuário do Instituto de Geociências , 40(1), pp. 180-190.), there are still gaps to be filled regarding the applicability and replicability of the methods in different areas, and the compatibility of the variables (Melelli 2014Melelli, L., 2014. Geodiversity: a new quantitative index for natural protected areas enhancement.Geojournal of tourism and geosites, 1(13), pp. 27-37.). At different cartographic scales and the choice of the elements that make up the abiotic environment and if they could be analyzed together (Gray 2013Gray, M., 2013. Geodiversity - Valuing and Conserving Abiotic Nature. New York: John Wiley and Sons.). In this context, this work aims to evaluate and compare models of geodiversity quantification based on geoprocessing techniques in the pilot areas: Chapada Diamantina National Park and Municipality of Morro do Chapéu, both are localized in the central region of the state of Bahia in Brazil.

2. Study Area, Materials and Methods

The methods were applied in two areas with different surfaces, but with similar physiographic contexts, Chapada Diamantina National Park and municipality of Morro do Chapéu (Figure 1).

Figure 1:
Location of municipality of Morro do Chapéu and Chapada Diamantina National Park highlighted in black and cyan, respectively. Besides main access roads and municipalities of the study areas in Chapada Diamantina with their respective altitudes.

Chapada Diamantina (Figure 1) encompasses the northern part of the Espinhaço Range, a set of disjoint mountains that extends from the state of Minas Gerais, towards the north, until reaching the São Francisco River (Misi and Silva 1996Misi, A., and Silva, M. D. G., 1994. Chapada Diamantina Oriental Bahia: geologia e depósitos. Salvador: Secretaria da Indústria, Comércio e Recursos Minerais.). This region occupies an area of approximately 65.000 km², in which approximately 75 municipalities are located. The region is characterized by a set of mountainous reliefs, plateaus, karst systems and sedimentary basins, developed essentially in rocks of sedimentary and metasedimentary nature, which are stratigraphically grouped in the Rio dos Remedios, Paraguaçu, Chapada Diamantina and Una Groups (Pereira 2010Pereira, R. G. F. A., 2010. Geoconservação e desenvolvimento sustentável na Chapada Diamantina (Bahia-Brasil). PhD. Universidade do Minho.).

Moreover, Chapada Diamantina is a division of the São Francisco valley to the west and the coast to the east, and is geographically divided into several mountain ranges, such as Rio de Contas, Bastião, Mangabeira and Sincorá. In the latter, located east of Chapada Diamantina, is the Chapada Diamantina National Park (PNCD).

This work was carried out in 5 stages. The summary of the steps is illustrated and numbered in the methodological flowchart shown in Figure 2.

In the first stage a bibliographic survey (1a) was made, and the choice of methods (1b) for geodiversity quantification. The criteria for choosing the methods were: conceptual and practical coherence, pioneering methodological development, methodological clarity and relevance to the scientific community (high number of citations and high impact factor). So, the methods that best met these criteria were Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) and Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.).

The method of Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) had the largest number of citations, so it was used as a theoretical basis for most works on geodiversity assessment and quantification. In summary, the generated index, called “Gd”, consists of the sum of physical elements present in a given area (geological, geomorphological, hydrological and pedological) multiplied by the roughness of the relief.

Figure 2:
Methods procedure used to quantify geodiversity and analyse in the municipality of Morro do Chapéu and Chapada Diamantina National Park.

The method of Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.) is derived from Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) method, however, instead of using territorial unit-based polygons as a municipality or region and a formula, it proposes the use of regular grids to calculate the geodiversity index or “Ig”, from the sum of subindices using as abiotic elements like structure, rock types, geomorphological units, soils, hydrography, mineral and fossiliferous occurrences.

Geodata acquisition and vector editing (2). At this stage the geographic databases were constructed with the following variables: geology, geomorphology, hydrography, pedology and mineral occurrences for the municipality of Morro do Chapéu (Rocha and Costa 1995Rocha, A. J. D., and Costa, I. V. G. D., 1995. Projeto Mapas Municipais. Município de Morro do Chapéu (BA) . Informações Básicas para o Planejamento e Administração do Meio Físico.), and the Chapada Diamantina National Park (CPRM 1994CPRM. 1994. Projeto Chapada Diamantina: Parque Nacional da Chapada Diamantina - BA: Informações Básicas para Gestão Territorial: Diagnóstico do Meio Físico e da Vegetação. Salvador, CPRM, IBAMA, pp.104) in two cartographic scales from 1: 100.000 and 1: 1.000.000 (CPRM 2006CPRM. 2006. Mapa Geodiversidade Brasil: Escala 1:2.500.000. Ministério das Minas e Energia. Secretaria de Geologia, Mineração e Transformação Mineral. Serviço Geológico do Brasil. Brasília/DF- Brasil. pp. 68 CD-ROM.).

So that there was no repetition in the geodiversity attribute count (sum), each feature class was joined, thus becoming “1”. In the case of hydrography, each hierarchical class (Strahler 1957Strahler, A. N., 1957. Quantitative analysis of watershed geomorphology. Eos, Transactions American Geophysical Union, 38(6), pp. 913-920.) was assigned a value of “1”.

Application of the methods (3). With the edited data, processing started on the Arcgis® package. For both methods, the same geodiversity elements based on Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.): geomorphological units, lithology, structure, hydrography, first order soils, mineral occurrences of mineral exploration, such as diamond mines. The fossil occurrences were not computed for lack of data.

In the modeling based on Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ), after generating the data using overlay tool was calculated by the original formula (1) and the formula without the roughness variable “R” (2). For roughness calculation, the slope of the terrain was first generated from the digital model elevation DEM from Japan Aerospace Exploration Agency, with a pixel size of 30 meters. After that, roughness values derived from the slope classes were determined according to Serrano e Ruiz - Flaño (2007)Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. .

G d = E g R / l n S (1)

G d = E g / l n S (2)

Equation (1) and (2) shows: Gd = Geodiversity Index; Eg = Number of physical elements (geomorphological, hydrological, soil) different existing in the unit; R = Roughness coefficient of the unit; S = Surface of the unit (km²).

Finally, with the results of the calculations, maps and graphs were prepared. To improve visualization, geodiversity indices were grouped into 5 class ranges using natural breaks (Jenks 1967) with the following nomenclatures: very low, low, medium, high and very high. This interval classification was made for both the Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) model maps and for the Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.), which will be seen below.

For the definition of grid sizes, the effective scale and minimum mappable area were first calculated (Forbes et al. 1982Forbes, T. and Rossiter, D.; D. and Wambeke, A. Van, 1982.Guidelines for evaluating the adequacy of soil resource inventories. Other. Soil Management Support Services, Ithaca, New York, USA.), it was defined that for scale 1: 100.000 the smallest polygon that would appear on the map was 0.25 km² and for scale to the millionth 25 km². Thus, regular hexagonal and square grids were generated from the minimum mappable area in the two worked scales (0.25 km² and 25 km²) and also intermediate sizes such as 1 km² and 4 km². Hexagon grids were generated from a script adapted from the tool that creates Thiessen polygons in the Arcgis® software.

After making the grids, they were overlapped in each theme (rocks, geomorphological units, structure, hydrography, mineral occurrences and soils), resulting in sub-index maps. After this step, the number of features found of the themes within each cell was calculated. The resulting sum value corresponds to the geodiversity index (Ig). These same procedures were done to scale to the millionth and in both pilot areas.

The fourth (4) step consisted of validating the map information against the reality in the field. Sixteen stopping points were predefined in the test areas (PNCD and Morro do Chapéu whose objective was to cross the widest range of different values of the geodiversity index in order to visually interpret the values.

Finally, an analysis of the methods was performed (5). For the model based on Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) the indices generated between equations (1) and (2) were compared in both study areas mapped on the 1: 100.000 scale. It is noteworthy that no map of the geodiversity index was generated on the millionth scale because this method was designed for medium and local scales.

From the maps generated based on the method Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.) was tried to compare by statistical analysis the indices by grid types, that is, square grid versus hexagonal grid and at different scales (1: 100.000 and 1: 1.000.000). Spatial analysis between types and grids and cartographic scale calculations were made using the difference between maps and the Kendal correlation (tau).

3. Results and discussions

3.1. Serrano and Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) applied method

The results obtained with the application of the Serrano & Ruiz - Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) method and its variation (without the roughness coefficient) are shown in table 1. And as a product, geodiversity maps with its variants (Figure 3 - A, B, C and D) and the graphs comparing the use of the roughness variable (Figure 3 - E1 and E2).

Table 1
Chapada Diamantina National Park and Morro do Chapéu: calculations for geodiversity indices.

Figure 3:
Map of the Chapada Diamantina National Park and Morro do Chapéu geodiversity index (A, C); Map of the geodiversity index without roughness (B, D); Graph of the variation between indices (E1, E2).

The indexes (Gd) calculated in the PNCD geomorphological units ranged from 4.5 in VII to 82.5 in XI. It is noted on the map (Figure 3 - A) that the “very high” class coincided with the unit with the largest area (70% of the total area). However, unit II, the smallest area (0.08% of the total area), obtained a value of 37.4. Thus, the second unit with the highest geodiversity index.

The same discrepancy in values (small areas with a high index) was found in a paper by Serrano and Ruiz-Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ). Although the use of natural logarithms had the function of smoothing abrupt values, when the values ​​of area (S) is less than or equal to “e” (Euler number), they generate an overvaluation of the index. Figure 4 illustrates this problem.

Figure 4:
Logarithmic function: y = ln (x) / x.

In Morro do Chapéu there were no discrepancies in the value of the index in relation to the area of the unit. However, when comparing the variation of R in the two pilot areas, it can be seen that in the PNCD the R enhances the final result of the index. Moreover, in Morro do Chapéu this variable does not interfere substantially in the result. This is due to the method to obtain the roughness. Even using the weighted average of the slopes for each unit in order to transform the slope intervals into R, the unit measurement interferes with the result. That is, the larger the unit, the greater the smoothing of slope averages. The reverse also occurs.

Serrano and Ruiz-Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ), state that the parameter R, should be studied more thoroughly and be tested in areas with slope variability. Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.) state that, depending on the area to be applied to the index, the result can be overestimated. Hjort and Luoto, (2010Hjort, J., and Luoto, M. (2010). Geodiversity of high-latitude landscapes in northern Finland.Geomorphology, 115(1-2), pp. 109-116.) did not use the roughness due to the low altimetric variation of their test area. It can still be said that this variable brings redundancy, of a geomorphological order, to the composition of the model.

Another problem that may arise in this model is when there are Units of the same class without contiguity in the territory, the final value may not be proportional in relation to the Unit with continuous territory.

In addition to the factors mentioned above, the choice of physical components found in the maps of geology, geomorphology and soils, which form “Eg” can influence the result of the index. For example, features represented as points (mineral resources) or lines (hydrography, faults and geological fractures) increase the index values disproportionately in relation to the features represented by polygons (soils, lithology and landforms).

In theory, this model should be able to compare geodiversity between different areas, but everything indicates that it is not possible.

3.2. Pereira et al. (2013Pereira, D. I., Pereira, P., Brilha, J., & Santos, L., 2013. Geodiversity assessment of Paraná State (Brazil): an innovative approach.Environmental management, 52(3), pp. 541-552.) applied method

Geodiversity maps were generated from the sub-indices in the scales 1: 100.000 and 1: 1.000.000 using square and hexagonal grids in the sizes 0.25 km², 1 km², 4 km² and 25 km².

The variations in the indices for the different study areas extracted by the different grids are shown in table 2. On the millionth scale, the lowest values exceed the lowest values of the indices generated with data on a 1: 100.000 scale. This shows how much the cartographic scale influences the geodiversity index. However, when comparing the maximum and minimum values of the indices at different scales, there seems to be no proportion in relation to the degree of generalization of the map. Therefore, even though the millionth scale has 10 times less levels of detail than 1: 100.000, there was a difference of 10 to 45 percent in the amplitude of these indices.

Table 2:
Variations in geodiversity indices (maximum and minimum) extracted by hexagonal, square grids on the 1: 100.000 and 1: 1.000.000 scales.

Table 3 and Table 4 show the Kendal correlation matrices. From them, it is possible to analyze the degree of self-similarity between pairs of maps with different scales, sizes and types of grids in the two pilot areas.

Then, as the grid size increases or decreases in both study areas, the index value changes gradually until there is no correlation between the indexes (τ = 0). For example, index values in a 0.25 km² square grid on the 1: 100.000 scale with a 1 km² square grid have 60% correlation, that is, the indexes are correlated, although low, and can be considered above 7 for values with strong correlation. If you compare the same square grid map of 0.25 km² with another of 25 km², the indices are 24% (weak spatial correlation). When comparing grids of the same area, but with data at different scales such as 1: 100.000 and 1: 1.000.000, there is little or no special correlation, and there are no patterns such as the gradual sequence of values according to combinations of grid sizes. Therefore, the choice of the cartographic scale of the variables also interferes with the value of the geodiversity index.

Table 3:
Kendall correlation matrix between maps of the geodiversity index: Chapada Diamantina National Park.

Table 4:
Kendall correlation matrix between maps of the geodiversity index: Morro do Chapéu.

When comparing the degree of self-similarity between hexagonal and square grids in different sizes, it was not possible to find conclusive answers about the performance of one type of grid in relation to another to calculate the indexes.

In Figure 5 a self-similarity test is shown: the difference between indices generated by square x hexagonal grids. Thus, in Morro do Chapéu there was a similarity of 47%. In the Chapada Diamantina National Park, 30% convergence between maps with the same grid size. Therefore, using the types of square or hexagonal grid can influence different results. With the tests carried out here, we do not have the necessary support to affirm which grid is better to quantify geodiversity. Thus, it can only be said that the hexagonal grid provides better aesthetic visualization on the map.

Figure 5:
Calculation of the difference in geodiversity indexes generated from hexagonal and square grids with 1 km² in size on the 1: 100.000 scale.

Other cartographic procedures that can help in choosing the grid is to understand the relationship between features represented by points, lines and polygons with the grid type where feature values are added, which result in a synthesis cartography. Thus, the understanding of the form factor, or form complexity index (S), which seeks to describe the general geometry of polygons in thematic maps, calculates the relationship between perimeter and area of each polygon (Hole 1978Hole, F. D. (1978). An approach to landscape analysis with emphasis on soils.Geoderma, 21(1), pp. 1-23.). In addition, as a way of reducing the ambiguity in the choice of grids to generate the geodiversity index, Pires (2018Pires, R. T., 2018. Estudo de métodos quantitativos da geodiversidade e sua aplicabilidade na Chapada Diamantina - BA. master thesis. Universidade Estadual de Feira de Santana.) suggests: using the effective scale calculation of Forbes et al. (1982Forbes, T. and Rossiter, D.; D. and Wambeke, A. Van, 1982.Guidelines for evaluating the adequacy of soil resource inventories. Other. Soil Management Support Services, Ithaca, New York, USA.) to define the grid size proportional to the scale available data: i) generate grids with sizes lower and higher than the created grid; ii) Generate the geodiversity index maps; iii) Calculate the arithmetic mean between the maps; and iv) generate a single synthetic map. This done, the relevance of the calculated average in relation to the universe should be tested. For this, the standard deviation of the data can be observed and use tests such as the Gamma coefficient and the uncertainty test.

3.3 Validation of Maps on the Field

The field evaluation did not aim to judge the official mappings, using them as a true model. In addition, as the main premise for this task, it focused on the analysis of the representativeness of geodiversity and its spatialization from the application of the methods.

Figure 6 shows one of the 16 visitation points where one of the highest values of the geodiversity index in the study areas was found. In this area, geological faults were found, 3 types of rocks, 3 types of soil, 2 types of geomorphological units and water bodies, totaling 10 natural features, that is, a geodiversity index equal to 10.

Figure 6:
Visiting point with geodiversity index = 10 in the National Park of the Chapada Diamantina.

Figure 7 shows the visitation point with the lowest value of the geodiversity index. In this area, 1 type of rock, 1 type of soil and 1 geomorphological unit were found, totaling 3 natural features, that is, a geodiversity index equal to 3.

After the fieldwork, it was found the difficulty of perceiving the diversity of physical features using maps based on the method of Serrano and Ruiz-Flaño, (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ). For the maps with the indexes extracted from grids, the values of the indexes generated were compatible with the reality in the field. However, it was noted that the smaller the grid, the greater the chances of the values being smaller due to the scope, especially when the abiotic elements have their features represented by points and lines. In addition, there is the aggravating geographic position of the grid, which depending on its location may include or exclude elements of geodiversity. This is because the grid is generated by default in the software from the polygon surrounding the study area. In larger grids, such as those of 25 km², the perception in loco of the physical elements is lost, due to the excessive scope. Therefore, among the maps with different grids taken to the field, the one with the best performance to understand the geodiversity was the 1 km² grid.

Figure 7:
Visiting point with geodiversity index = 3 in Morro do Chapéu.

4. Conclusion

In view of the arguments presented, the main conclusions of this work and the resulting recommendations were scored:

  1. For areas with strong slope variations, the inclusion of the roughness coefficient contributes to determining the values of the geodiversity index (Gd). In flat areas with a slope lower than 5° degrees, the coefficient of roughness does not affect the final value. Further research that uses indirect methods to assess geodiversity must be developed, as well as testing other ways to extract the roughness of the landscape;

  2. A paradox was found in the formula for the geodiversity index of Serrano and Ruiz-Flaño (2007Serrano, E., and Ruiz-Flaño, P., 2007. Geodiversity: a theoretical and applied concept.Geographica Helvetica , 62(3), pp. 140-147. ) in relation to the use of ln as the denominator. It is concluded that, areas smaller than the Euler number generate hyper valued indexes, and depending on the thresholds in the logarithmic scale, territories with size variation between Units may have the geodiversity index overestimated or underestimated. Therefore, this limitation of the studied method sheds light on the importance of auditing the data before incorporating them into the modeling;

  3. The effective scale calculation should be used as a parameter in relation to the minimum grid size. It is also suggested to use arithmetic media of values of the geodiversity index strained by different grid sizes. Therefore, it is necessary to advance in studies that aim to create cartographic parameters that involve the scales of the base maps with the maximum grid sizes.

  4. The indices generated from cartographic bases to the millionth need further studies. It should be sought what elements and levels of geodiversity should be included in the model for small scales;

  5. As it was found that the physical attributes represented on the map by points overvalue the composition of the index, it is recommended to use the elements represented by points in a superimposed way on the geodiversity map or to create an index based on weighted values.

ACKNOWLEDGEMENT

The authors acknowledge the support provided by CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior) and INCT - IN TREE (Instituto Nacional de Ciência e Tecnologia - estudos interdisciplinares e transdisciplinares em ecologia e evolução).

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Publication Dates

  • Publication in this collection
    07 Oct 2022
  • Date of issue
    2022

History

  • Received
    07 Dec 2021
  • Accepted
    13 June 2022
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