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Canesin, T. S., Brilha, J., & Díaz-Martínez, E. (2020). Best practices and constraints in geopark management: Comparative analysis of two Spanish UNESCO Global Geoparks. Geoheritage, 12(1), 14.Search in Google Scholar
Ramsay, T. (2017). Fforest Fawr Geopark—a UNESCO Global Geopark distinguished by its geological, industrial and cultural heritage. Proceedings of the Geologists’ Association, 128(3), 500-509.Search in Google Scholar
Ferreira, D. R., & Valdati, J. (2023). Geoparks and sustainable development: Systematic review. Geoheritage, 15(1), 6.Search in Google Scholar
Du, Y., & Girault, Y. (2018). A genealogy of UNESCO global geopark: emergence and evolution. International Journal of Geoheritage and Parks, 6(2), 1-17.Search in Google Scholar
Lee, K. C., & Karimova, P. G. (2021). From cultural landscape to aspiring geopark: 15 years of community-based landscape tourism in Fengnan Village, Hualien County, Taiwan (2006–2021). Geosciences, 11(8), 310.Search in Google Scholar
Lewis, I. D. (2023). Evolution of geotourism in Australia from Kanawinka global geopark and Australian national landscapes to georegions and geotrails: a review and lessons learned. Land, 12(6), 1190.Search in Google Scholar
Porshnov, D., Burlakovs, J., Kriipsalu, M., Pilecka, J., Grinfelde, I., Jani, Y., & Hogland, W. (2019). Geoparks in cultural and landscape preservation context. Research for Rural Development, 1.Search in Google Scholar
Campbell, H., & Masser, I. (2020). GIS In Organizations: How Effective Are GIS In Practice?. CRC Press.Search in Google Scholar
Fischer, M. M. (Ed.). (2019). Spatial analytical perspectives on GIS. Routledge.Search in Google Scholar
Ricker, B., & Thatcher, J. (2017). Evolving technology, shifting expectations: cultivating pedagogy for a rapidly changing GIS landscape. Journal of Geography in Higher Education, 41(3), 368-382.Search in Google Scholar
Ouchra, H., Belangour, A., & Erraissi, A. (2022, October). Spatial Data Mining technology for GIS: a review. In 2022 International Conference on Data Analytics for Business and Industry (ICDABI) (pp. 655-659). IEEE.Search in Google Scholar
Molokáč, M., Babicová, Z., Pachinger, P., & Kornecká, E. (2023). Evaluation of geosites from the perspective of geopark management: the example of proposed Zemplín Geopark. Geoheritage, 15(4), 129.Search in Google Scholar
Stepišnik, U., & Trenchovska, A. (2018). A new quantitative model for comprehensive geodiversity evaluation: the Škocjan Caves Regional Park, Slovenia. Geoheritage, 10, 39-48.Search in Google Scholar
Lee, S., Lee, S., Lee, M. J., & Jung, H. S. (2018). Spatial assessment of urban flood susceptibility using data mining and geographic information System (GIS) tools. Sustainability, 10(3), 648.Search in Google Scholar
Thakur, J. K., Singh, S. K., & Ekanthalu, V. S. (2017). Integrating remote sensing, geographic information systems and global positioning system techniques with hydrological modeling. Applied Water Science, 7(4), 1595-1608.Search in Google Scholar
Pham, T. T., Dang, K. B., Giang, T. L., Hoang, T. H. N., & Ha, H. N. (2024). Deep learning models for monitoring landscape changes in a UNESCO Global Geopark. Journal of Environmental Management, 354, 120497.Search in Google Scholar
Shi, Y., Gao, H., Tan, S., Qin, H., Tian, Z., Meng, J., & Zheng, X. (2024). Pattern change and ecological risk analysis of Shilin World Geopark landscape. Frontiers in Ecology and Evolution, 12, 1341969.Search in Google Scholar
Kocheeva, N. A., Iurkova, N. A., Sukhova, M. G., Redkin, A. G., & Zhuravleva, O. V. (2021). Geospatial potential and environmental changes: case study of complex nature of the Altai Geopark. Journal of Water and Land Development.Search in Google Scholar
