Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia

Geodiversity, comprising both endogenous and exogenous geological processes, plays a crucial role in shaping the structure and functionality of natural systems, alongside its substantial impact on human well-being. However, the often-overlooked interconnection between geodiversity components limits...
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Gespeichert in:

Autor*in:	Alejandro Arias-Díaz [verfasserIn] Hugo Murcia [verfasserIn] Felipe Vallejo-Hincapié [verfasserIn] Károly Németh [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2023

Schlagwörter:	geodiversity quantification geodiversity index geosystem services sustainability northern Andes

Übergeordnetes Werk:	In: Land - MDPI AG, 2013, 12(2023), 11, p 2053
Übergeordnetes Werk:	volume:12 ; year:2023 ; number:11, p 2053

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/land12112053

Katalog-ID:	DOAJ101223196

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author	Alejandro Arias-Díaz
spellingShingle	Alejandro Arias-Díaz misc geodiversity quantification misc geodiversity index misc geosystem services misc sustainability misc northern Andes misc Agriculture misc S Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia
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topic_title	Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia geodiversity quantification geodiversity index geosystem services sustainability northern Andes
topic	misc geodiversity quantification misc geodiversity index misc geosystem services misc sustainability misc northern Andes misc Agriculture misc S
topic_unstemmed	misc geodiversity quantification misc geodiversity index misc geosystem services misc sustainability misc northern Andes misc Agriculture misc S
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title	Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia
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title_full	Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia
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title_sort	understanding geodiversity for sustainable development in the chinchiná river basin, caldas, colombia
title_auth	Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia
abstract	Geodiversity, comprising both endogenous and exogenous geological processes, plays a crucial role in shaping the structure and functionality of natural systems, alongside its substantial impact on human well-being. However, the often-overlooked interconnection between geodiversity components limits our comprehension of geosystems. In the Chinchiná River Basin (CRB) in Colombia, located in the northern Andes in South America, we established criteria to differentiate geodiversity classes, calculated indices to understand the distribution of geological elements, and discussed systemic relationships. This comprehensive approach lays the foundation for a holistic comprehension of the territory’s structure and functionality. Our findings revealed the convergence in an area of 1052 km<sup<2</sup< of 10 rock types, 7 slope ranges, 13 landforms, 5 drainage density features, 610.4 km of faults with 9 kinematic tendencies, 5 soil orders, 5 climate types, a 3328 km surface drainage network with 7 hydrographic orders, 1 underground aquifer, 4 areas with lakes, 2 zones with glaciers, 27 polygenetic and monogenetic volcanoes, and several thermal springs. This discussion explores the implications of various methodologies used to establish the value of the general geodiversity index while also examining the relationships between abiotic elements and their distribution patterns. This forms a fundamental basis for understanding the geosystem services of the basin in terms of regulation, support, and provisioning processes, as well as the culture and knowledge derived from geodiversity. These conceptual elements are indispensable for enhancing the sustainability of a region that is susceptible to the impacts of climate change. Furthermore, they serve as the foundations for the objective’s achievement, as set by the UNESCO Global Geopark project “Volcán del Ruiz”, currently ongoing within the region.
abstractGer	Geodiversity, comprising both endogenous and exogenous geological processes, plays a crucial role in shaping the structure and functionality of natural systems, alongside its substantial impact on human well-being. However, the often-overlooked interconnection between geodiversity components limits our comprehension of geosystems. In the Chinchiná River Basin (CRB) in Colombia, located in the northern Andes in South America, we established criteria to differentiate geodiversity classes, calculated indices to understand the distribution of geological elements, and discussed systemic relationships. This comprehensive approach lays the foundation for a holistic comprehension of the territory’s structure and functionality. Our findings revealed the convergence in an area of 1052 km<sup<2</sup< of 10 rock types, 7 slope ranges, 13 landforms, 5 drainage density features, 610.4 km of faults with 9 kinematic tendencies, 5 soil orders, 5 climate types, a 3328 km surface drainage network with 7 hydrographic orders, 1 underground aquifer, 4 areas with lakes, 2 zones with glaciers, 27 polygenetic and monogenetic volcanoes, and several thermal springs. This discussion explores the implications of various methodologies used to establish the value of the general geodiversity index while also examining the relationships between abiotic elements and their distribution patterns. This forms a fundamental basis for understanding the geosystem services of the basin in terms of regulation, support, and provisioning processes, as well as the culture and knowledge derived from geodiversity. These conceptual elements are indispensable for enhancing the sustainability of a region that is susceptible to the impacts of climate change. Furthermore, they serve as the foundations for the objective’s achievement, as set by the UNESCO Global Geopark project “Volcán del Ruiz”, currently ongoing within the region.
abstract_unstemmed	Geodiversity, comprising both endogenous and exogenous geological processes, plays a crucial role in shaping the structure and functionality of natural systems, alongside its substantial impact on human well-being. However, the often-overlooked interconnection between geodiversity components limits our comprehension of geosystems. In the Chinchiná River Basin (CRB) in Colombia, located in the northern Andes in South America, we established criteria to differentiate geodiversity classes, calculated indices to understand the distribution of geological elements, and discussed systemic relationships. This comprehensive approach lays the foundation for a holistic comprehension of the territory’s structure and functionality. Our findings revealed the convergence in an area of 1052 km<sup<2</sup< of 10 rock types, 7 slope ranges, 13 landforms, 5 drainage density features, 610.4 km of faults with 9 kinematic tendencies, 5 soil orders, 5 climate types, a 3328 km surface drainage network with 7 hydrographic orders, 1 underground aquifer, 4 areas with lakes, 2 zones with glaciers, 27 polygenetic and monogenetic volcanoes, and several thermal springs. This discussion explores the implications of various methodologies used to establish the value of the general geodiversity index while also examining the relationships between abiotic elements and their distribution patterns. This forms a fundamental basis for understanding the geosystem services of the basin in terms of regulation, support, and provisioning processes, as well as the culture and knowledge derived from geodiversity. These conceptual elements are indispensable for enhancing the sustainability of a region that is susceptible to the impacts of climate change. Furthermore, they serve as the foundations for the objective’s achievement, as set by the UNESCO Global Geopark project “Volcán del Ruiz”, currently ongoing within the region.
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title_short	Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia
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Understanding Geodiversity for Sustainable Development in the Chinchiná River Basin, Caldas, Colombia

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