PDF
Abstract
Globally, deserts are considered as fragile and unique biomes. They not only have the capacity to provide various ecosystem services, and possess great tourism potential and scientific value, but also are susceptible to modifications or alterations in their geomorphology. Despite the strategic importance of these ecosystems at a global level, there is limited specialized research directed towards the study of deserts in Ecuador. The purpose of this research is to determine the susceptibility to degradation and carrying capacity of environmental units to support tourist and recreational activities, thereby offering the community a sustainable resource over time. The delimitation of environmental units was carried out based on the identification of land use and land cover through the supervised classification method. Multicriteria analysis was used to obtain the areas susceptible to degradation, where the environmental units were evaluated through expert evaluation. Once the results of the previous methodologies were obtained, areas with environmental and tourist potential were identified using the hosting capacity matrix, which is based on anthropic activities developed in the area. Subsequently, a proposal for conservation strategies and activities at the national and local levels was formulated. Five categories of land use and land cover were identified, resulting in 11 environmental units represented in spatial data. It was determined that approximately 31% of the territory is more susceptible to degradation, while the remaining 69% is less susceptible. Based on the susceptibility of these areas, 7 activities and 2 tourist routes were designated to help reduce anthropogenic pressure. Additionally, the community was provided with 5 proposals for conservation strategies at the national level, 4 at the local level, and 4 activities to be developed based on the findings identified during the investigation. This highlights the significant potential that the Palmira Desert has to become a conservation area.
Keywords
desert
/
geographic information system
/
hosting capacity
/
environmental units
/
conservation strategies
/
Ecuador
Cite this article
Download citation ▾
Kathleen Allyn Vélez-Macías, José Luis Sánchez-Cortez, Vinicio Xavier Macas-Espinosa.
Characterization and evaluation of environmental units as a management and conservation strategy of the Palmira Desert (Ecuador).
International Journal of Geoheritage and Parks, 2024, 12(3): 446-464 DOI:10.1016/j.ijgeop.2024.07.009
| [1] |
K.A.N. Adiat, M.N.M. Nawawi, K. Abdullah. Assessing the accuracy of GIS-based elementary multi criteria decision analysis as a spatial prediction tool: A case of predicting potential zones of sustainable groundwater resources. Journal of Hydrology, 440-441 (2012), pp. 75-89, 10.1016/j.jhydrol.2012.03.028
|
| [2] |
S.R. Akbarian Ronizi, M. Mokarram, S. Negahban. Investigation of sustainable rural tourism activities with different risk: A GIS-MCDM case in Isfahan, Iran. Earth and Space Science, 10 (4) (2023). e2021EA002153. https://doi.org/10.1029/2021EA002153
|
| [3] |
A.J.B. Andrade, N.P.P. Barbosa. Combinação do Método AHP e SIG na Seleção de Áreas com Potenciais para a Instalação de Aterro Sanitário: Caso da Ilha Do Fogo, Na República de Cabo Verde [Combination of the AHP method and GIS in the selection of areas with potential for the installation of a landfill: Case of Fogo Island, in the Republic of Cape Verde]. Revista de Geografía (UFPE), 32 (2) (2015), pp. 248-266
|
| [4] |
C.X. Bustos, C.M. Bermúdez. Determinación y comparación de índices de erosión teóricos en cuencas del flanco surandino venezolano, apoyado en sistemas de información geográfica y programación python [Determination and comparison of theoretical erosion indices in basins of the southern Andean flank of Venezuela, supported by geographic information systems and Python programming]. Terra Nueva Etapa, 33 (53) (2017), pp. 105-122
|
| [5] |
D.A. Casquete-Moscoso.Delimitación de áreas con fines de conservación al suroeste de la parroquia Urbana de Guayaquil [Delimitation of conservation areas to the southwest of the urban parish of Guayaquil] (Undergraduate thesis). University of Guayaquil, Ecuador (2018). http://repositorio.ug.edu.ec/handle/redug/29412
|
| [6] |
A. Cerda, H. Lavee. Correntia y erosion en los suelos del desierto de judea [Runoff and erosion in the soils of the Judean Desert]. Geographicalia, 32 (1995), pp. 17-36, 10.26754/ojs_geoph/geoph.1995321720
|
| [7] |
M. Conforti, S. Pascale, G. Robustelli, F. Sdao. Evaluation of prediction capability of the artificial neural networks for mapping landslide susceptibility in the Turbolo River catchment (northern Calabria, Italy). Catena, 113 (2014), pp. 236-250, 10.1016/j.catena.2013.08.006
|
| [8] |
M. Costa-Cabral, S.J. Burges. Digital elevation model networks (DEMON): A model of flow over hillslopes for computation of contributing and dispersal areas. Surface Water and Climate, 30 (6) (1994), pp. 1681-1692, 10.1029/93WR03512
|
| [9] |
J. Deza. Indicadores de cambios climáticos en el desierto [Indicators of climate change in the desert]. Ciencia y Desarrollo, 19 (2) (2016), pp. 55-73, 10.21503/cyd.v19i2.1307
|
| [10] |
El Universo (2021). Palmira, un extraordinario lugar desértico en medio del Ecuador [Palmira, an extraordinary desert place in the middle of Ecuador]. Retrieved from https://www.eluniverso.com/larevista/2021/02/06/nota/9613428/palmira-extraordinario-lugar-desertico-medio-ecuador/.
|
| [11] |
C.M. García. Rally Dakar: Las consecuencias para el paisaje del desierto y el turismo [Dakar Rally: Consequences for desert landscape and tourism]. Diario U Chile (2014, January 20). Retrieved from https://radio.uchile.cl/2014/01/20/rally-dakar-las-consecuencias-para-el-paisaje-del-desierto-y-el-turismo/
|
| [12] |
Gobierno Nacional del Ecuador (2008). Constitución de la República del Ecuador [The constitution of the Republic of Ecuador is the supreme legal norm that governs Ecuador]. Retrieved from https://www.defensa.gob.ec/wp-content/uploads/downloads/2021/02/Constitucion-de-la-Republica-del-Ecuador_act_ene-2021.pdf.
|
| [13] |
Gobierno de España.Guía para la estimación de absorciones de dióxido de carbono [Guide for the estimation of carbon dioxide absorptions]. Retrieved from https://www.miteco.gob.es/content/dam/miteco/es/cambio-climatico/temas/mitigacion-politicas-y-medidas/guiapa_tcm30-479094.pdf (2024)
|
| [14] |
Gobierno Nacional del Ecuador.Procedimientos para la Declaración y Gestión de Áreas Protegidas [Procedures for the declaration and management of protected areas]. (2016). Retrieved from https://www.gob.ec/sites/default/files/regulations/2018-09/Documento_Procedimientos-Declaraci%C3%B3n-y-Gesti%C3%B3n-%C3%81reas-Protegidas-Subsistemas.pdf
|
| [15] |
Gobierno Nacional del Ecuador.Código Orgánico del Ambiente [The “Código Orgánico del Ambiente” is the set of legal regulations that govern environmental management in Ecuador]. Retrieved from https://www.ambiente.gob.ec/wp-content/uploads/downloads/2018/01/CODIGO_ORGANICO_AMBIENTE.pdf (2017)
|
| [16] |
D. Gómez-Orea. Ordenacion territorial [Territorial planning]. Ediciones Mundi Prensa, Madrid (2007)
|
| [17] |
A. Gonzáles-Serrano, R. Ordóñez-Octavo.Análisis del Impacto en la Red Eléctrica al Adicionar Nueva Capacidad en la CNLV [Analysis of the impact on the electric grid when adding new capacity at CNLV]. (2011). Retrieved from http://132.248.9.195/ptb2011/julio/0670829/Index.html
|
| [18] |
C. González-Pavón, C.V. Palau, J.M. Juárez, V. Estruch-Guitart, S. Guillem-Picó, I. Balbastre-Peralta. Optimization of collective irrigation network layout through the application of the analytic hierarchy process (AHP) multicriteria analysis method. Water, 16 (3) (2024), p. 370, 10.3390/w16030370
|
| [19] |
I. Guechi, H. Gherraz, A. Korichi, D. Alkama. Predicting archaeological sites locations in desert areas, using GIS-AHP-GeoTOPSIS model: Southwestern Algeria, Bechar. Archaeologies, 19 (2) (2023), pp. 471-499, 10.1007/s11759-023-09479-0
|
| [20] |
J.N. Guerra-Ramirez. Habitar el desierto: Transicion Energética y Transformación del Proyecto Habitacional Colectivo en la Ecología del Desierto de Atacama [Inhabiting the desert: Energy transition and transformation of the collective housing project within the ecology of the Atacama Desert]. Universitat Politecnica de Catalunya, España (2003)
|
| [21] |
B.K.P. Horn. Hill shading and the reflectance map. Proceedings of the IEEE, 69 (1) (1981), pp. 14-47, 10.1109/PROC.1981.11918
|
| [22] |
Instituto Geográfico Militar. Ríos de Ecuador [Rivers of Ecuador]. Spatial data file format (shapefile). Instituto Geográfico Militar, Ecuador (2013)
|
| [23] |
International Union for Conservation of Nature (IUCN). Deserts on the world heritage list: Filling the gaps. Retrieved from https://www.iucn.org/es/content/desiertos-en-la-lista-de-patrimonio-mundial-a-llenar-los-vacios#:-:text=Los%20desiertos%20y%20sus%20habitantes,y%20la%20recolecci%C3%B3n%20de%20le%C3%B1a (2010)
|
| [24] |
B.S. Jabar, K.N. Sayl, R. Alboresha. Incorporating a GIS-based approach and SWAT model to estimate sediment in the Western Desert of Iraq. International Journal of Design & Nature and Ecodynamics, 18 (4) (2023), pp. 791-800, 10.18280/ijdne.180405
|
| [25] |
Jatun Sacha Foundation.Cobertura vegetal y uso actual del suelo [Vegetation cover and current land use]. Retrieved from https://gis.uazuay.edu.ec/descargas/promsa/metadatos/c-uso_de_suelo.pdf (2003)
|
| [26] |
R.-L. José, K. Ulrich. Uso del índice topográfico de humedad (ith) para el diagnóstico de la amenaza por desborde fluvial, Trujillo-Venezuela [Use of the topographic wetness index (TWI) for the diagnosis of the river overflow threat, Trujillo state-Venezuela]. Revista Geográfica Venezolana, 53 (1) (2012), pp. 109-126
|
| [27] |
T. Kang, S. Yang, J.Y. Bu, J.H. Chen, Y.C. Gao. Quantitative assessment for the dynamics of the main ecosystem services and their interactions in the northwestern arid area, China. Sustainability, 12 (3) (2020), 10.3390/su12030803
|
| [28] |
A. Karmaoui. Drought and desertification in Moroccan Pre-Sahara, Draa valleys: Exploring from the perspective of young people. Geoenvironmental Disasters, 6 (2019), p. 2, 10.1186/s40677-019-0118-8
|
| [29] |
D.A. Keith, J.R. Ferrer-Paris, E. Nicholson, R. Kingsford. The IUCN global ecosystem typology 2.0: Descriptive profiles for biomes and ecosystem functional groups. IUCN, Gland (2020), pp. 61-66
|
| [30] |
G.K.L. Lee, E.H.W. Chan. The analytic hierarchy process (AHP) approach for assessment of urban renewal proposals. Social Indicators Research, 89 (1) (2008), pp. 155-168, 10.1007/s11205-007-9228-x
|
| [31] |
X. Lian, S.L. Piao, A. Chen, C. Huntingford, B.J. Fu, L.Z.X. Li, … M.L. Roderick. Multifaceted characteristics of dryland aridity changes in a warming world. Nature Reviews Earth and Environment, 2 (4) (2021), pp. 232-250, 10.1038/s43017-021-00144-0
|
| [32] |
F.T. Maestre, B.M. Benito, M. Berdugo, L. Concostrina-Zubiri, M. Delgado-Baquerizo, D.J. Eldridge, … S. Soliveres. Biogeography of global drylands. New Phytologist, 231 (2) (2021), pp. 540-558, 10.1111/nph.17395
|
| [33] |
C. Martínez López, A.O. Rivera Paja, J.C. Menjivar Flores. Susceptibility to erosion risks in soils dedicated to pineapple cultivation in the department of Valle del Cauca, Colombia. Earth Sciences Research Journal, 25 (2) (2021), pp. 201-206, 10.15446/esrj.v25n2.84601
|
| [34] |
J. Martínez Valderrama. Los desiertos y la desertificación [The deserts and desertification]. Editorial CSIC Consejo Superior de Investigaciones Científicas, Madrid (2017)
|
| [35] |
P. Mattivi, F. Franci, A. Lambertini, G. Bitelli. TWI computation: A comparison of different open source GISs. Open Geospatial Data, Software and Standards, 4 (2019), p. 6, 10.1186/s40965-019-0066-y
|
| [36] |
Ministerio de Agricultura y Ganadería. Modelo Digital de Elevaciones-3 metros [Digital elevation model-3 meters]. Ministry of Agriculture and Livestock of Ecuador, Guayaquil (2016)
|
| [37] |
Ministerio del Ambiente, Agua y Transición Ecológica Ministry of environment water, and ecological transition.Agua y Transición Ecológica. Ministerio del Ambiente, Retrieved from http://areasprotegidas.ambiente.gob.ec/es/content/categor%C3%ADas-de-manejo (2015)
|
| [38] |
O.A. Mohammed, K.N. Sayl, S.O. Sulaiman, N.S. Mahmood, M.F. Allawi, N. Al-Ansari. Geoinformatics-based approach for aquifer research zone identification in the western desert of Iraq. International Journal of Geomate, 25 (110) (2023), pp. 220-234. https://geomatejournal.com/geomate/article/view/3448/3272
|
| [39] |
M.C. Morillo Moreno. Turismo y producto turistico. Evolución, conceptos, componentes y clasificación [Tourism and tourist product. Evolution, concepts, components, and classification]. Visión Gerencial, 10 (1) (2011), pp. 135-158
|
| [40] |
S. Mozzicafreddo, J. Ortega, N. Papa, P.J. Torre.Delimitación de zonas de manejo utilizando variables topograficas y mapas de rendimiento [Delimitation of management zones using topographic variables and yield maps]. Retrieved from https://rdu.unc.edu.ar/bitstream/handle/11086/11254/Delimitaci%c3%b3n%20de%20zonas%20de%20manejo%20utilizando%20variables%20topogr%c3%a1ficas%20y%20mapas%20de%20rendimiento.pdf?sequence=4&isAllowed=y (2018)
|
| [41] |
E.A. Nantes. El método analytic hierarchy process para la toma de decisiones: Repaso de la metodología y aplicaciones [The analytic hierarchy process method for decision-making: Review of methodology and applications]. Revista De La Escuela De Perfeccionamiento En Investigacion Operativa, 27 (46) (2019), pp. 54-73
|
| [42] |
M. Oliva, L. Culqui-Mirano, S. Leiva, R. Collazos, R. Salas, H. Vásquez, J.L. Maicelo-Quintana. Reserva de carbono en un sistema silvopastoril compuesto de Pinus patula y herbáceas nativas [Carbon reserve in a silvopastoral system composed of Pinus patula and native herbaceous plants]. Scientia Agropecuaria, 8 (2) (2017), pp. 149-157, 10.17268/sci.agropecu.2017.02.07
|
| [43] |
N. Oliveira-Santos, R.A. Souza-Machado, R.C. Louis-González. Identification of levels of anthropization and its implications in the process of desertification in the caatinga biome (Jeremoabo, Bahia-Brazil). Cuadernos de Investigación Geográfica, 48 (1) (2022), pp. 41-57, 10.18172/cig.5212
|
| [44] |
Organization of American States.Comisión Mixta de Cooperación Amazónica-Ecuatoriano-Colombiana-Plan de Ordenamiento y Manejo de las Cuencas de los Ríos San Miguel y Putumayo [Joint commission for Amazonian cooperation-Ecuadorian-Colombian-watershed planning and management plan for the San Miguel and Putumayo Rivers]. Retrieved from https://oas.org/usde/publications/Unit/oea32s/oea32s.pdf (1987)
|
| [45] |
S.C. Pal, U. Chatterjee, R. Chakrabortty, P. Roy, I. Chowdhuri, A. Saha, … K. Islam.Anthropogenic drivers induced desertification under changing climate: Issues, policy interventions, and the way forward. Progress in Disaster Science, 20 (2023), Article 100303, 10.1016/j.pdisas.2023.100303
|
| [46] |
I. Pérez-Rubio, D. Flores, C. Vargas, A. Mende, F. Jiménez. Análisis comparativo de susceptibilidad de erosión y evaluación de incertidumbre en la subcuenca del Río Claro, Costa Rica [Comparative analysis of erosion susceptibility and uncertainty assessment in the Claro River Subbasin, Costa Rica]. Revista de Ciencias Ambientales, 55 (1) (2021), pp. 271-293, 10.15359/rca.55-1.13
|
| [47] |
Piqueras V.Y. (2022). Cálculo de la consistencia y el vector propio en AHP [Calculation of consistency and eigenvector in AHP]. Retrieved from https://victoryepes.blogs.upv.es/2022/02/15/calculo-de-la-consistencia-y-el-vector-propio-en-ahp/.
|
| [48] |
P. Quinn, K. Beven, P. Chevalier, O. Planchon. The prediction of hillslope flow paths for distributed hydrological modelling using digital terrain models. Hydrological Processes, 5 (1) (1991), pp. 59-79, 10.1002/hyp.3360050106
|
| [49] |
P. Ranjan, P.K. Pandey, V. Pandey. Groundwater spring potential zonation using AHP and fuzzy-AHP in eastern Himalayan region: Papum Pare District, Arunachal Pradesh, India. Environmental Science and Pollution Research, 31 (7) (2024), pp. 10317-10333, 10.1007/s11356-023-26769-w
|
| [50] |
N.J.C. Rodríguez. Ecoturismo y turismo cultural: Impactos positivos y negativos en el departamento de Boyacá Colombia [Ecoturism and cultural tourism: Positive and negative impacts in the department of Boyacá Colombia]. Turismo y Patrimonio, 17 (2021), pp. 29-43, 10.24265/turpatrim.2021.n17.02
|
| [51] |
T.L. Saaty. Decision making with the analytic hierarchy process. International Journal of Quality and Service Sciences, 1 (1) (2008), pp. 83-98, 10.1504/IJSSCI.2008.017590
|
| [52] |
Y.M. Sameer, A.N. Abed, K.N. Sayl. Highway route selection using GIS and analytical hierarchy process case study Ramadi Heet rural highway. Journal of Physics: Conference Series, 1973 (1) (2021), Article 012060, 10.1088/1742-6596/1973/1/012060
|
| [53] |
Y.M. Sameer, A.N. Abed, K.N. Sayl. Geomatics-based approach for highway route selection. Applied Geomatics, 15 (1) (2023), pp. 161-176, 10.1007/s12518-023-00495-x
|
| [54] |
N.G. Sánchez. Zonificación ecológica: Unidades Ambientales Integradas (UAIs) como herramienta base de diagnóstico y gestión [Ecological zoning: Integrated environmental units (IEUs) as a diagnostic and management tool]. Acta Nova, 9 (3) (2019), pp. 417-428
|
| [55] |
Santillán P.M.L. (2019). Desiertos, espacios de interacción y amplia diversidad biológica [Deserts, spaces of interaction and wide biological diversity]. Retrieved from https://ciencia.unam.mx/leer/902/desiertos-espacios-de-interaccion-y-amplia-diversidad-biologica.
|
| [56] |
L. Schwimer, R. Galili, N. Porat, G. Bar-Oz, D. Nadel, S.A. Rosen. The constructed desert: A sacred cultural landscape at Har Tzuriaz, Negev, Israel. Cambridge Archaeological Journal, 34 (2) (2023), pp. 271-289, 10.1017/S0959774323000276
|
| [57] |
T. Sharma, O. Singh. Soil erosion susceptibility assessment through geo-statistical. Modeling Earth Systems and Environment, 3 (2) (2017), pp. 733-753, 10.1007/s40808-017-0331-y
|
| [58] |
R.L. Soteres, E.A. Sagredo, P.I. Moreno, T.V. Lowell, B.V. Alloway. Glacial geomorphology of the central and southern Chilotan archipelago (42.2°S-43.5°S), northwestern Patagonia. Journal of Maps, 18 (2) (2022), pp. 151-167, 10.1080/17445647.2021.2008538
|
| [59] |
J. Sun, N.A. Wang, Z.M. Niu. Effect of soil environment on species diversity of desert plant communities. Plants, 12 (19) (2023), p. 3465, 10.3390/plants12193465
|
| [60] |
H. Taherdoost, M. Madanchián. Métodos y conceptos de toma de decisiones de criterios múltiples (MCDM) [Multi-criteria decision making (MCDM) methods and concepts]. Enciclopedia, 3 (1) (2023), pp. 77-87, 10.3390/encyclopedia3010006
|
| [61] |
B. Thair-Mitab, R. Mozahim-Hamdoon, K. Naba-Sayl. Assessing potential landfill sites using GIS and remote sensing techniques: A case study in Kirkuk, Iraq. International Journal of Design & Nature and Ecodynamics, 18 (3) (2023), pp. 643-652, 10.18280/ijdne.180316
|
| [62] |
United Nations. Agenda 21. Author, New York City (1992)
|
| [63] |
Universidad de Murcia. Tema 9:Classification. Retrieved from www.um. es/geograf/sigmur/teledet/tema09.pdf (2003)
|
| [64] |
K. Vélez Macías.Análisis de las unidades ambientales con fines de conservación en el Desierto de Palmira, Comunidad Galte Jatun Loma [Analysis of environmental units for conservation purposes in the Palmira Desert, Galte Jatun Loma Community] (Unpublished master’s thesis). Universidad de Guayaquil, Ecuador (2023)
|
| [65] |
F.L. Wei, S. Wang, M. Brandt, B.J. Fu, M.E. Meadows, L.X. Wang, … R. Fensholt. Responses and feedbacks of African dryland ecosystems to environmental changes. Current Opinion in Environmental Sustainability, 48 (2021), pp. 29-35, 10.1016/j.cosust.2020.09.004
|
| [66] |
World Tourism Organization (UNWTO). Sustainable development of tourism in deserts: Guide for decision makers (English version). Author, Madrid (2007), 10.18111/9789284411931
|
| [67] |
D.W. Xu, B.R. Chen, B.B. Shen, X. Wang, Y. Yan, L.J. Xu, X.P. Xin. The classification of grassland types based on object-based image analysis with multisource data. Rangeland Ecology & Management, 72 (2) (2019), pp. 318-326, 10.1016/j.rama.2018.11.007
|
| [68] |
Y.M. Zhang, A. Tariq, A.C. Hughes, D.Y. Hong, F.W. Wei, H. Sun, … K.P. Ma.Challenges and solutions to biodiversity conservation in arid lands. Science of the Total Environment, 857 (2023), Article 159695, 10.1016/j.scitotenv.2022.159695
|
