Η παρούσα διατριβή πραγματεύεται τη διαχείριση της Γεωλογικής Κληρονομιάς με τη συμβολή της Τηλεπισκόπησης και των GIS. Η έννοια της γεωλογικής κληρονομιάς περικλείει χαρακτηριστικές γεωμορφές, πετρώματα, απολιθώματα, αποθέσεις και διαδικασίες, οι οποίες συνθέτουν τη γεωλογική ιστορία κάθε περιοχής. Η γεωλογική ιστορία κάθε περιοχής αποτελεί αναπόσπαστο κομμάτι της ευρύτερης ιστορίας της Γης, η οποία με τη σειρά της συνδέεται με τους ανθρώπους και τον πολιτισμό τους. Η διαχείριση της γεωλογικής κληρονομίας περιλαμβάνει ένα φάσμα σταδίων. Η Τηλεπισκόπηση και τα GIS, συνιστούν επιστήμες και εργαλεία - που έχουν σημειώσει τα τελευταία χρόνια άλματα προόδου και βρίσκουν εφαρμογή σε πολλά επιστημονικά πεδία και κατ’επέκταση στη Γεωλογία. Ο κύριος σκοπός της διατριβής είναι η μελέτη και ανάδειξη προηγμένων μεθόδων Τηλεπισκόπησης και GIS, στην εν γένει διαχείριση της γεωλογικής κληρονομιάς. Στο πλαίσιο της λήφθηκαν υπόψη και διερευνήθηκαν τρεις βασικοί τύποι Τηλεπισκόπησης, σε συνδυασμό με τα GIS, όπου αυτό κρίθηκε σκόπιμο/εφικτό. Η εφαρμογή και διερεύνηση των δυνατοτήτων της Τηλεπισκόπησης και GIS έλαβε χώρα υπό τη μορφή περιπτωσιολογικών μελετών, οι οποίες καλύπτουν όλο το φάσμα των χαρτογραφικών κλιμάκων. Οι κλίμακες αντιστοιχούν σε εθνική, μικρή, μεσαία και μεγάλη. Αφορούν μία χώρα, επιμέρους περιοχές, γεωμορφές, αντικείμενα, που μπορούν να χαρακτηριστούν ως γεωλογική κληρονομιά. Διερευνήθηκαν οι εν λόγω δυνατότητες σε όλα τα επιμέρους βήματα διαχείρισης της γεωλογικής κληρονομιάς. Η ιδιαιτερότητα και πρωτοτυπία της διατριβής αφορά αρχικά στη συσχέτιση της γεωλογικής κληρονομιάς με την επιστήμη της Τηλεπισκόπησης και τα GIS, καθώς και στην κατά περίπτωση ακρίβεια απόδοσης της πληροφορίας. Μελετήθηκε η γεωλογική κληρονομιά σε όλες τις κλίμακες, δίνοντας τη δυνατότητα να εφαρμοστούν οι τρεις τύποι της Τηλεπισκόπησης και να εξεταστούν ως προς την συμβολή τους σε κάθε στάδιο της διαχείρισης της γεωλογικής κληρονομιάς. Η μελέτη αυτή συμπληρώνεται μέσω της εξέτασης της χρήσης των GIS στα στάδια διαχείρισης. Τα αποτελέσματα όλων των σταδίων μελέτης της συμβολής των δυο αντικειμένων σε σχέση με τη γεωλογική κληρονομιά του Ελληνικού χώρου χρησιμοποιούνται επίσης σε μια πρακτική εφαρμογή στην εκπαιδευτική διαδικασία, ως χαρακτηριστικό παράδειγμα αξιοποίησής τους στα ανώτερα στάδια διαχείρισης. Η ανάπτυξη της βάση δεδομένων για τη γεωκληρονομιά της Ελλάδας σε περιβάλλον GIS, παρέχει πληροφορίες με όσο το δυνατό μεγαλύτερη χωρική ακρίβεια, η οποία επιτρέπει το συνδυασμό με περαιτέρω τηλεπισκοπικά και άλλα γεωχωρικά προϊόντα/πληροφορίες. Με αυτόν τον τρόπο, προκύπτουν νέα στοιχεία για τη γεωκληρονομιά σε τοπικό, περιφερειακό και εθνικό επίπεδο, τα οποία δε μπορούσαν να εξαχθούν μέχρι σήμερα σε αυτήν την έκταση και ακρίβεια. Σημαντικό είναι, ότι η ύπαρξη της γεωβάσης ανοίγει πολλές μελλοντικές δυνατότητες αξιοποίησής της από κάθε ενδιαφερόμενο χρήστη, σε συνδυασμό με κάθε είδους σχετική γεωχωρική πληροφορία. Αναφορικά με την πρωτοτυπία στις επιμέρους περιπτωσιολογικές μελέτες στις τρεις βασικές κλίμακες, τεκμηριώνονται ψηφιακά σημαντικά στοιχεία γεωκληρονομιάς, ενώ μελετώνται διάφορες παράμετροι της γεωκληρονομιάς της Μήλου. Επιπλέον, ως προς τα ανώτερα στάδια διαχείρισης, τεκμηριώνεται η συμβολή των γεωχωρικών δεδομένων για εκπαιδευτικούς σκοπούς σε διαφορετικές συνθήκες και ακροατήρια. Τέλος, διατυπώνονται επιστημονικά τεκμηριωμένες προτάσεις αξιοποίησης της Τηλεπισκόπησης και των GIS για τη διαχείριση της γεωλογικής κληρονομιάς. Με βάση τα αποτελέσματα της διατριβής παρέχονται κατευθυντήριες γραμμές με τη μορφή πινάκων, ως προς τη χρήση γεωχωρικών δεδομένων, συναρτήσει της κλίμακας και του σταδίου διαχείρισης της γεωκληρονομιάς.

The present doctoral thesis investigates the management of Geological Heritage, focusing on the contribution of Remote Sensing and GIS. The concept of geological heritage includes characteristic or even rare landforms, rocks, fossils, deposits and processes, which make up the geological history of each region. The geological history of each region is an integral part of the wider history of the Earth, which in turn is linked to people and their culture. The management of geological heritage includes a wide range of stages. Remote Sensing, as well as GIS, are both sciences and tools that have rapidly evolved in recent years and have found application in different scientific fields, among which that of Geology. The main purpose of this thesis is to study and showcase advanced Remote Sensing methods and GIS, in the broader management of geological heritage. In the framework of the thesis, three main types of Remote Sensing were considered and investigated, in combination with GIS, where this was deemed appropriate/feasible. The application and investigation of the potentialities of Remote Sensing and GIS were examined in the form of case studies, which cover the entire range of cartographic scales. The scales correspond to national, small, medium and large. These potentialities were explored in all individual steps of geological heritage management. The distinctive quality and originality of the thesis concern firstly the holistic association of the geological heritage with the science of Remote Sensing and GIS, as well as the accuracy of the relevant information for each case study. Geological heritage was studied at all scales, while all three types of Remote Sensing were applied and examined in terms of contribution to each stage of geological heritage management. This study is complemented by the examination of the use of GIS in the management stages. Part of the results were also applied, as an additional case study, in the educational process, as a characteristic example of their utilization in higher stages of management. The development of a database for the geoheritage of Greece in a GIS environment provides information with as much spatial accuracy as possible, which allows for their combination with further remote sensing and other geospatial products/information. With this, new data on geoheritage at the local, regional and national level emerge, which could not be collected to this extent and precision to date. It is important to note that the existence of the geodatabase allows for many future possibilities for its utilization by any interested user, in combination with any kind of relevant geospatial information. Concerning the originality of the individual case studies at the three main scales, important geoheritage elements are digitally documented, while various parameters of the geoheritage of Milos Island are studied, as indicative cases of the contribution of geospatial technologies and data. Furthermore, regarding the higher stages of management, and in particular the exploitation of geoheritage, the contribution of geospatial data to educational purposes in different circumstances and for different audiences is documented with tangible and measurable results in the last case study. Scientifically substantiated proposals for the purposeful utilization of Remote Sensing and GIS in geological heritage management are propounded. Finally, based on the results of the thesis, ensemble guidelines are provided in the form of tables, regarding the use of geospatial data, in relation to the scale and stage of geoheritage management.

Abdel-Maksoud, K.M. Emam, M.A. (2019). Hidden geology in Ancient Egypt, Geoheritage, 11, 897–907.

Abdullah Q.A. (2014). Classification of the Unmanned Aerial Systems.

Agapiou A., Lysandrou V., Alexakis D., Themistocleous K., Cuca B., Argyriou A., Sarris A., Hadjimitsis D. (2015). Cultural heritage management and monitoring using remote sensing data and GIS: The case study of Paphos area, Cyprus, Elsevier, Computers, Environment and Urban Systems 54 230 – 239 http://dx.doi.org/10.1016/j.compenvurbsys.2015.09.003.

Allen, T.F.H., Starr, T.B. (1982). Hierarchy Perspectives for Ecological Complexity. University of Chicago Press.

AL-Saedi M., Almulla S., Jassem R. (2022). Applied remote sensing technique, and GIS to choose suitable Geopark in south east Iraq, Journal of Pharmaceutical Negative Results, Volume 13, Special Issue 6, DOI: 10.47750/pnr.2022.13.S06.419.

Austin, R. (2010). Unmanned Aircraft Systems: UAVs Design, development and deployment, United Kingdom: Wiley.

Australian Heritage Commission. (1996). Australian Natural Heritage Charter for conservation of places of natural heritage significance. Published by the Australian

Committee for the International Union for the Conservation of Nature (ACIUCN), Australian Heritage Commission, Canberra, ACT.

Avery, T. E., Berlin, G.L. (1992). Fundamentals of Remote Sensing and Airphoto Interpretation (5th edition). New York: Mc Millan Publishing Company.

Ballarin M., Balletti C., Vernier P. (2020). Replicas In Cultural Heritage: 3d Printing And The Museum Experience, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-2, 2018 ISPRS TC II Mid-term Symposium “Towards Photogrammetry 2020”, 4–7 June 2018, Riva del Garda,Italy, https://doi.org/10.5194/isprs-archives-XLII-2-55-2018.

Ballesteros D., Caldevilla P., Vila R., Barros X., Rodríguez‑Rodríguez L., García‑Ávila M., Sahuquillo E., Llorente M., Diez J., Fuertes‑Fuente M., Timón‑Sánchez S., Lombera‑Hermida A., Álvarez I., Pérez‑Cáceres I., Acebo M., Amaré P., García J., Martín‑González F., Alemparte M. (2022). A GIS‑supported Multidisciplinary Database for the Management of UNESCO Global Geoparks: the Courel Mountains Geopark (Spain), Geoheritage, https://doi.org/10.1007/s12371-022-00654-3.

Bamler, R., Hartl, P. (1998). Synthetic aperture radar interferometry. Inverse Problems 14, R1–R54.

Barrett E.C., Curtis L.F. (1982). Introduction to Environmental Remote Sensing, London, John Wiley and Sons, Halsted Press.

Barsi J, Schott J.,Hook S., Raqueno N., Markham B.,Radocinski R. (2014). Landsat-8 Thermal Infrared Sensor (TIRS) Vicarious Radiometric Calibration, Remote Sensing, ISSN 2072-4292.

Baryshnikov, G.F., Tsoukala, E. (2010). New analysis of the Pleistocene carnivores from Petralona Cave (Macedonia, Greece) based on the Collection of the Thessaloniki Aristotle University. Geobios, 43: 389-402,

Belward, A.S., Skøien, J.O. (2015). Who launched what, when and why; trends in global land-cover observation capacity from civilian earth observation satellites. ISPRS Journal of Photogrammetry and Remote Sensing. 103. pp. 115–128.

Berardino, P., Fornaro, G., Lanari, R., Sansosti, E. (2002). A new algorithm for surface deformation monitoring based on small baseline differential SAR interferograms. IEEE Transactions on Geoscience and Remote Sens., 40, pp. 2375−2383.

Bernhard Rabus, Michael Eineder, Achim Roth, Richard Bamler, The shuttle radar topography mission—a new class of digital elevation models acquired by spaceborne radar, ISPRS Journal of Photogrammetry and Remote Sensing, Volume 57, Issue 4, (2003), Pages 241-262, ISSN 0924-2716, https://doi.org/10.1016/S0924-2716(02)00124-7 (https://www.sciencedirect.com/science/article/pii/S0924271602001247)

Bobrowsky P., Cronin V.S., Di Capua G., Kieffer S.W., Peppoloni S. (2017). The Emerging Field of Geoethics. In: Scientific Integrity and Ethics with Applications to the Geosciences, edited by L.C. Gundersen. Special Publication American Geophysical Union, John Wiley and Sons, Inc.

Bollati, I., Pelfini, M., & Pellegrini, L. (2012). A geomorphosites selection method for educational purposes: a case study in Trebbia Valley (Emilia Romagna, Italy). Geogr. Fis. Din. Quat., 35(1), 23–35.

Bonham-Carter, G. (1994). Geographic information systems for geoscientists: modelling with GIS. Oxford; New York: Pergamon.

Bowman, B. (2015). Teacher knowledge and geospatial technologies, Conversations on Knowledge for Teaching Education Technologies: Now and in the Future, conversationsonkft.weebly.com.

Bradbury J. (1993). A Preliminary Geoheritage Inventory of the Eastern Tasmania Terrane. A Report to Parks and Wildlife Service, Tasmania.

Brilha H. (2002). Geoconservation and protected areas. Environmental Conservation 29(3): 273-276.

Brilha J. (2016). Inventory and Quantitative Assessment of Geosites and Geodiversity Sites: a Review, Geoheritage, 8:119–134 DOI 10.1007/s12371-014-0139-3.

Brocx M., Semeniuk V. (2007). Geoheritage and geoconservation - history, definition, scope and scale, Journal of the Royal Society of Western Australia, 90: 53-87.

Brocx M., Semeniuk V. (2015). Using the Geoheritage Tool-Kit to Identify Inter-related Geological Features at Various Scales for Designating Geoparks: Case Studies from Western Australia Springer International Publishing Switzerland, E. Errami et al. (eds.), From Geoheritage to Geoparks, Geoheritage, Geoparks and Geotourism, DOI 10.1007/978-3-319-10708-0_17.

Brocx Μ., Semeniuk V. (2015). Geology: From Antiquity to Modern Day Geoheritage and Geoconservation, with Britain as a Case Study, Springer International Publishing Switzerland, E. Errami et al. (eds.), From Geoheritage to Geoparks, Geoheritage, Geoparks and Geotourism, DOI 10.1007/978-3-319-10708-0_3.

Brutto M. Lo, Garraffa A., Meli P. (2014). UAV Platforms For Cultural Heritage Survey: First Results, ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume II-5, 2014 ISPRS Technical Commission V Symposium, 23 – 25 June 2014, Riva del Garda, Italy.

Burlando M., Firpo M., Queirolo C., Rovere A., Vacchi M. (2011). From Geoheritage to Sustainable Development: Strategies and Perspectives in the Beigua Geopark (Italy), Geoheritage, 3:63–72, Springer, DOI 10.1007/s12371-010-0019-4.

Burrough P.A. (1986). Principles of Geographical Information Systems for land Resources Assessment, Oxford University Press, New York.

Calvo J.,Triantaphyllou M.,Requeiro M.,Stamatakis M., (2012), Alternating diatomaceous and volcaniclastic deposits in Milos Island, Greece. A contribution to the upper Pliocene–lower Pleistocene stratigraphy of the Aegean Sea, Palaeogeography, Palaeoclimatology, Palaeoecology 321–322, Elsevier

Campbell, B.J. (1996). Introduction to Remote Sensing. New York, London: Virginia Polytechnic Institute and State University, The Guilford Publications Press, 2nd edition.

Carcavilla L., Durán Valsero J., García-Cortés, Á., López-Martínez J. (2009). Geological Heritage and Geoconservation in Spain: Past, Present, and Future. Geoheritage, 75–91.

Carton A., Coratza P., Marchetti M. (2005). Guidelines for geomorphological sites mapping: examples from Italy. Géomorphologie: Relief, Processus, Environnement. n° 3 Géomorphosites: définition,évaluation et cartographie 11(3):209–218. https://doi.org/10.4000/geomorphologie.374.

Cayla N. (2014). An Overview of New Technologies Applied to the Management of Geoheritage, Geoheritage 6:91–102, DOI 10.1007/s12371-014-0113-0.

Chen F., You J., Tang P., Zhou W., Masini N., Lasaponara R. (2017). Unique performance of spaceborne SAR remote sensing incultural heritage applications: Overviews and perspectives, Archaeological Prospection. 25:71–79, John Wiley & Sons, Ltd.

Clark, D.B., Read, J.M., Clark, M.L., Cruz, A.M., Dotti, M.F, Clark, D.A. (2004). Application of 1-m and 4-m resolution satellite data to ecological studies of tropical rain forests. Ecological Applications. 14 (1). pp. 61–74.

Cowley D. (2010). Remote Sensing for Archaeological Heritage Management, 11th EAC Heritage Management Symposium, Reykjavík, Iceland, 25-27 March 2010, EAC Occasional Paper No. 5, Europae Archaeologia Consilium (EAC), Association Internationale sans But Lucratif (AISBL), Siège social.

Crofts R., Gordon J. (2014). Geoconservation in protected areas, parks vol 20.2 November, 10.2305/IUCN.CH.2014.PARKS-20-2.RC.en.

Cuca B., Hadjimitsis D. (2017). Space technology meets policy: An overview of Earth Observation sensors for monitoring of cultural landscapes within policy framework for

Cultural Heritage, Elsevier, http://dx.doi.org/10.1016/j.jasrep.2017.05.001.

Cushnie, J.L. (1987). The interactive effect of spatial resolution and degree of internal variability within land-cover types on classification accuracies. International Journal of Remote Sensing. 8 (1). pp. 15–29.

DeMiguel D., Brilha J., Alegret L., Arenillas I., Arz J. A., Gilabert, V.,Strani, F., Valenciano, A., Villas, E., Azanza, B. (2021). Linking geological heritage and geoethics with a particular emphasis on palaeontological heritage: the new concept of “palaeontoethics”, Geoheritage 13:69 https://doi.org/10.1007/s12371-021-00595-3.

Daskalopoulou K., Gagliano A., Calabrese S., Manfredi L., Hantzis K., Kyriakopoulos K., Walter A. (2018), Gas geochemistry and CO2 output estimation at the island of Milos, Greece, Journal of Volcanology and Geothermal Research, Elsevier

Deroina J P., Rania Bou Kheirb, Abdallah C. (2017). Geoarchaeological remote sensing survey for cultural heritage management. Case study from Byblos (Jbail, Lebanon), Journal of Cultural Heritage 23 37–43, Elsevier, http:// dx.doi.org/10.1016/ j.culher.2016.04.014.

Dhanda A., Reina Ortiz M., Weigert A., Paladini A., Min A., Gyi M., Su S., Fai S., Santana Quintero M. (2019). Recreating Cultural Heritage Environments For Vr Using Photogrammetry, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-2/W9, 8th Intl. Workshop 3D-ARCH “3D Virtual Reconstruction and Visualization of Complex Architectures”, 6–8 February 2019, Bergamo, Italy, https://doi.org/10.5194/isprs-archives-XLII-2-W9-305-2019.

Dingwall P., Weighell T., Badman T. (2005). Geological world heritage: a global framework, A Contribution to the Global Theme Study of World Heritage Natural Sites, Protected Area Programme, IUCN.

Dixon G. (1996). Geoconservation: an international review and strategy for Tasmania. Miscellaneous Report, Parks & Wildlife Service, Tasmania, 101pp.

Dowling R.K. (2013). Global Geotourism – An Emerging Form of Sustainable Tourism. Czech Journal of Tourism 2(2): 59–79. DOI: 10.2478/cjot-2013-0004.

Droj G. (2010). Cultural Heritage Conservation by GIS, https:// www.researchgate.net/publication/236161824.

Dungan, J.L., Perry, J.N., Dale, M.R.T., Legendre, P., Citron-Pousty, S., Fortin, M.-J., Jakomulska, A., Miriti, M. & Rosenberg, M.S. (2002). A balanced view of scale in spatial statistical analysis. Ecography, 25 (February), pp. 626–640.

Eberhard, R. (ed) 1997 Pattern & Process: Towards a regional approach to National Estate assessment of geodiversity. Environment Australia Technical Series No 2.

Elfadaly, A., Shams Eldein A., Lasaponara R. (2020). Cultural Heritage Management Using Remote Sensing Data and GIS Techniques around the Archaeological Area of Ancient Jeddah in Jeddah City, Saudi Arabia, Sustainability, 12, 240; doi:10.3390/su12010240.

Emery, B., Camps, A., Rodriguez-Cassola, M. (2017). Introduction to Satellite Remote Sensing: Atmosphere, Ocean, Land and Cryosphere Applications. 1st edition. Amsterdam, Netherlands; Cambridge, MA: Elsevier.

Erikstad L. (2012). Geoheritage and geodiversity management – the questions for tomorrow, Elsevier, http://dx.doi.org/10.1016/j.pgeola.2012.07.003.

Errami E., Schneider G., Ennih N., Randrianaly H.N., Bendaoud A., Noubhani A., Norman N., Allan M., Vasconcelos L., Costa L., Al-Wosabi M., Al-Subbary A., Mabvuto-

Ngwira P., Okunlola G., Lawal Halliru S., Andrianaivo L., Siby S., Ketchemen B., Gauly M., Hassine M., Azki F., Juliette T., Lattrache K., Omulo M., Bobrowsky P. (2015).

Geoheritage and Geoparks in Africa and the Middle-East: Challenges and Perspectives Springer International Publishing Switzerland E. Errami et al. (eds.), From

Geoheritage to Geoparks, Geoheritage, Geoparks and Geotourism, DOI 10.1007/978-3-319-10708-0_1.

Farr, T. G., Kobrick, M. (2000). Shuttle Radar Topography Mission produces a wealth of data, Amer. Geophys. Union Eos, 81, 583-585.

Fassoulas C., Mouriki D., Dimitriou-Nikolakis P., Iliopoulos G. (2011). Quantitative Assessment of Geotopes as an Effective Tool for Geoheritage Management, Geoheritage 4:177–193,DOI 10.1007/s12371-011-0046-900.

Ferretti, A., Monti-Guarnieri, A., Prati, C., Rocca, F., Massonnet, D. (2007). InSAR Principles: Guidelines for SAR Interferometry Processing and Interpretation, ESA TM-19, ESA Publications Division, Noordwijk, The Netherlands.

Ferretti, A., Prati, C., Rocca, F. (2000). Nonlinear subsidence rate estimation using permanent scatterers in differential SAR interferometry. IEEE Trans. Geosci. Remote Sens. 38, pp. 2202 – 2212.

Ferretti, A., Prati, C., Rocca, F. (2001). Permanent scatterers in SAR interferometry. IEEE Trans. Geosci. Remote Sens. 39, pp. 8 – 20.

Foumelis, M., Delgado Blasco,J.-M., Brito,F., Pacini,F., Papageorgiou, E., Pishehvar, P., P. Bally (2022). "SNAPPING Services on the Geohazards Exploitation Platform for Copernicus Sentinel-1 Surface Motion Mapping" Remote Sensing 14, no. 23: 6075. https://doi.org/10.3390/rs14236075.

Fytikas, M., Marinelli, G. (1976). Geology and geothermics of the island of Milos (Greece) (No. NP-22876). Institute of Geology and Mining Research, Athens (Greece); Pisa Univ. (Italy). Instituto di Mineralogia e Petrografia.

Fytikas, M., Innocenti, F., Kolios, N., Manetti, P., Mazzuoli, R., Poli, G., Villari, L., (1986). Volcanology and petrology of volcanic products from the island of Milos and neighbouring islets. Journal of Volcanology and Geothermal Research, 28(3-4), 297-317.

Gabriel, A.K. and Goldstein, R.M. (1988). Crossed orbit interferometry: theory and experimental results from SIR-B. Int. J. Remote Sens. 9, pp. 857–72.

Gabriel, A.K., Goldstein, R.M., Zebker, H.A. (1989). Mapping small elevation changes over large areas: differential radar interferometry. J. Geophys. Res. 94, pp. 9183–91.

Gahegan, M., Ehlers, M. (2000). A framework for the modelling of uncertainty between remote sensing and geographic information systems. ISPRS Journal of Photogrammetry and Remote Sensing, 55, 176–188.

Ganas A., Karakonstantis A., Kapetanidis V., Tsironi V., Karamitros I., Efstathiou E., Karasante I., Kassaras I. (2022), Ground deformation and microseismicity patterns onshore Milos, Cyclades, Greece, 16th International Congress of the Geological Society of Greece, 17-19/10/2022, Patra Greece, Bulletin of the Geological Society of Greece

Ganesh B., Vincent S., Pathan S., Benitez S. (2022). Machine learning based landslide susceptibility mapping models and GB-SAR based landslide deformation monitoring systems: Growth and evolution, Elsevier, https:// doi.org/ 10.1016/ j.rsase.2022.100905.

Geological Society of Australia. (2006). Heritage Policy. Geological Society of Australia Inc., Sydney, NSW.

Georgopoulos A., Oikonomou C., Adamopoulos E., Stathopoulou E.K. (2016). Evaluating Unmanned Aerial Platforms For Cultural Heritage Large Scale Mapping, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLI-B5, 2016, XXIII ISPRS Congress, 12–19 July 2016, Prague,

Czech Republic, doi:10.5194/isprsarchives-XLI-B5-355-2016.

Gerhard Krieger, Manfred Zink, Markus Bachmann, Benjamin Bräutigam, Daniel Schulze, Michele Martone, Paola Rizzoli, Ulrich Steinbrecher, John Walter Antony, Francesco De Zan, Irena Hajnsek, Kostas Papathanassiou, Florian Kugler, Marc Rodriguez Cassola, Marwan Younis, Stefan Baumgartner, Paco López-Dekker, Pau Prats, Alberto Moreira,TanDEM-X: A radar interferometer with two formation-flying satellites, Acta Astronautica,Volume 89,2013,Pages 83-98,ISSN 0094 5765, https://doi.org/10.1016/j.actaastro.2013.03.008.

Gonggrijp G. P. (1999). Geodiversity: the key to a holistic approach in renaturation. In: D Barettino, M Vallejo, & E Gallego (eds), Towards the balanced Management and conservation of the geological heritage in the new millennium. Sociedad Geológica de Espana, Madrid, 77-80.

Goodchild, M.F. (2006). Geographical information science: fifteen years later. In P.F. Fisher editor, Classics from IJGIS: Twenty years of the International Journal of

Geographical Information Science and Systems. Boca Raton: CRC Press, 424, 199–204.

Goodchild, M.F. (2011). Scale in GIS: An overview. Geomorphology. 130 (1–2). p.pp. 5–9.

Gordon G., Crofts R., Díaz-Martínez E., Woo K. (2018). Enhancing the Role of Geoconservation in Protected Area Management and Nature Conservation, Geoheritage 10:191–203 DOI 10.1007/s12371-017-0240-5.

Goussios D., Faraslis I. (2022). Integrated Remote Sensing and 3D GIS Methodology to Strengthen Public Participation and Identify Cultural Resources, Land, 11, 1657. https://doi.org/10.3390/land11101657.

Gray, M. (2008). Geodiversity: developing the paradigm. Proceedings of the Geologists' Association, 119, 287–298

Greenwood F. (2015). Drones and Aerial Observation: New Technologies for Property Rights, Human Rights, And Global Development A Primer – Section How to Make Maps With Drones, pp. 35, New America.

Hadjimitsis D., Agapiou A., Alexakis D., Sarris A. (2013). Exploring natural and anthropogenic risk for cultural heritage in Cyprus using remote sensing and GIS, International Journal of Digital Earth, 2013 Vol. 6, No. 2, 115 142, http://dx.doi.org/10.1080/17538947.2011.602119.

Hadjimitsis D., Cuca B., Lysandrou V., Masini., Themistocleous K., Agapiou A., Lasaponara R., Schreier G. (2020). Remote Sensing for Archaeology and Cultural Landscapes, Best Practices and Perspectives Across Europe and the Middle East, Springer Remote Sensing/Photogrammetry ISBN 978-3-030-10978-3 ISBN 978-3-030-10979-0 (eBook) https://doi.org/10.1007/978-3-030-10979-0.

Haidu I. (2016). What is Technical Geography – a letter from the editor. Geographia Technica. 11: 1–5. doi:10.21163/GT_2016.111.01.

Hasiuk F. (2014). Making things geological: 3D printing in the geosciences, GSA Today, v. 24, no. 8, doi: 10.1130/GSATG211GW.1.

He P., Cheng X., Liu Y. (2020). Research on the Application of Space Information Technology in Geoheritages for Land-use Planning Purposes, WMCAUS, IOP Conf. Series: Materials Science and Engineering 960042106 IOP Publishing doi:10.1088/1757-899X/960/4/042106.

Henriques M.H., R. P. dos Reis, Brilha J., Mota T. (2011). Geoconservation as an Emerging Geoscience, Geoheritage 3:117–128DOI 10.1007/s12371-011-0039-8.

Herrera-Franco, G., Carrión-Mero, P., Montalván-Burbano, N., Caicedo-Potosí, J., Berrezueta, E. (2022). Geoheritage and Geosites: A Bibliometric Analysis and Literature Review. Geosciences, 12, 169. https:// doi.org /10.3390/ geosciences12040169.

Hooper, A., Segall, P., Zebker, H. (2007). Persistent scatterer interferometric synthetic aperture radar for crustal deformation analysis, with application to Volcán Alcedo,

Galápagos. J. Geophys. Res., 112, B07407, doi: 10.1029/2006JB004763.

Hrasna M. (2002). Geoenvironment and geofactors of the environment-the basic concepts of environmental geology, Acta Geologica Univ. Com. Bratislava, No 57.

Hua Wu and Zhao-Liang Li, 2009, Scale Issues in Remote Sensing: A Review on Analysis, Processing and Modeling, Review, Sensors 2009, 9, 1768-1793; doi:10.3390/s90301768

Ilinca V., Milu V., Peligrad S., Gheuca I. (2022). The Albeşti Limestone: a geoheritage and cultural heritage in Romania, Journal of Maps, Taylor & Francis Group, https://doi.org/10.1080/17445647.2022.2135465.

Jensen, J.R. (2004). Introductory Digital Image Processing. 3rd Ed. Upper Saddle River, NJ, USA: Prentice Hall.

Jensen, J.R. (2007). Remote Sensing of the Environment: An Earth Resource Perspective. 2nd ed. Upper Saddle River, N.J.: Pearson Prentice Hall.

Jones E.,Hall A. (2010), Stypteria phorime as alunogen in solution: Possible pointer to the gradual cooling of the Melos geothermal system

Jong, S.M. De, Meer, F.D. Van der. (2004). Remote Sensing Image Analysis: Including the Spatial Domain. Remote Sensing and Digital Image Processing. S. M. De Jong & F. D. Van der Meer (eds.). Dordrecht: Springer Netherlands.

Joyce E. B. (1997). Assessing Geological Heritage In: R. Eberhard (ed), Pattern & Processes: Towards a Regional Approach to National Estate assessment of geodiversity. Environment Australia Technical Series No 2, Canberra, ACT, pp. 37-39.

Karagianni A. (2021). Terrestrial Laser Scanning And Satellite Data In Cultural Heritage Building Documentation, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLVI-M-1-2021 28th CIPA Symposium “Great Learning & Digital Emotion”, 28 August–1 September 2021, Beijing, China.

Katsanos, G., Karakasi, K. E., Karolos, I. A., Kofinas, A., Antoniadis, N., Tsioukas, V., & Tsoulfas, G. (2022). Volumetric assessment of hepatic grafts using a light detection and ranging system for 3D scanning: Preliminary data. World Journal of Hepatology, 14(7), 1504.

Kepalaitė I. (2015). The Importance of Geoheritage and Geo Top of the Charts in Environmental Studies, Environment, Proceedings of the 10th International Scientific and

Practical Conference. Volume II, 133-136 Technology. Resources, Rezekne, Latvia.

Kiernan K. (1997). Landform classification for geoconservation. In:R Eberhard (ed), Pattern & Processes: Towards a Regional Approach to National Estate assessment of geodiversity. Environment Australia Technical Series No 2.

Kohl M., Magnussen S.S., Marchetti M. (2006). Sampling methods, remote sensing and GIS multiresource forest inventory.

Komoo I. (2000). Geoheritage Conservation and its Potential for Geopark Development in Asia - Oceania. Geoparks Review Office of the World Geoparks Network, Beijing, China.

Kozlowski. (1999). Programme of geodiversity conservation in Poland. Polish Geological Institute Special Papers 2: 15-18.

Krieger, Gerhard, Manfred Zink, Markus Bachmann, Benjamin Bräutigam, Daniel Schulze, Michele Martone, Paola Rizzoli. (2013). “TanDEM-X: A Radar Interferometer with Two Formation-Flying Satellites.” Acta Astronautica 89 (August): 83–98. https://doi.org/10.1016/j.actaastro.2013.03.008.

Lam, N.S.-N. (2004). Fractals and Scale in Environmental Assessment and Monitoring. In: Scale and geographic inquiry: Nature, society, and method. Blackwell Publishing.

Legge P., King R. (1992). Geological Society of Australia Inc Policy on Geological Heritage in Australia. The Australian Geologist 85: 18-19.

Leontaritis A., Kouli K., Pavlopoulos K., (2020), The glacial history of Greece: a comprehensive review, Mediterranean Geoscience Reviews (2020) 2:65–90, https://doi.org/10.1007/s42990-020-00021-w, Springer

Levin, N. (1999). Fundamentals of Remote Sensing. Remote Sensing Laboratory, Geography Department, Tel Aviv University, GIS unit, The society for the Protection of Nature in Israel.

Liang, S. and Wang, J. (2020). Advanced remote sensing: terrestrial information extraction and applications. Second edition. Amsterdam: Academic Press.

Lillesand, T., Kiefer, R. W. and Chipman, J. (2015). Remote Sensing and Image Interpretation, 7th Edition. 7th edition. Wiley.

Liu, J. G. and Mason, P. J. (2016). Image Processing and GIS for Remote Sensing: Techniques and Applications. 2nd edition. Wiley-Blackwell.

Lloyd, C. D. (2010). Spatial data analysis: an introduction for GIS users. Oxford; New York: Oxford University Press.

Loon, A. J. V. (2008). Geological education of the future. Earth-Science Reviews, 86, 247–254

Lou U., Wu S., You C., Chung C., Valsami E., Baltatziz E. (2023), Lithium isotope systematics and water/rock interactions in a shallow-water hydrothermal system at Milos island, Greeece, Marine Chemistry, Elsevier

Loveland, T. R., Dwyer, J. L. (2012). Landsat: Building a strong future. Remote Sensing of Environment 122: 22–29, doi: 10.1016/j.rse.2011.09.022.

Lozios, S., Soukis, K., & Antoniou, V. (2015). Τοπογραφικοί χάρτες και μορφολογικές δομές αναγλύφου [Chapter]. In Lozios, S., Soukis, K., & Antoniou, V. 2015. Γεωλογική χαρτογράφηση και ασκήσεις υπαίθρου [Undergraduate textbook]. Kallipos, Open Academic Editions. https://hdl.handle.net/11419/1269

Lucie Kubalíková, Karel Kirchner, Aleš Bajer. (2021). Geomorphological Resources for Geoeducation and Geotourism, Springer Nature Singapore Pte Ltd. R. B. Singh et al. (eds.), Global Geographical Heritage, Geoparks and Geotourism, Advances in Geographical and Environmental Sciences, https://doi.org/10.1007/978-981-15-4956-4_18

Lukinbeal, C. (2016). Scale and Its Histories. Yearbook of the Association of Pacific Coast Geographers. 78 (1). pp. 15–27.

Maguire D.J., (1991). An overview and definition of GIS, in D.J. Maguire et al. (ed), Geographical Information Systems: Principles and applications. Longman Scientific &

Technical, London, pp.9-20.

MaKinster, J., Trautmann, N. &Barnett, M. (2014). Teaching science and investigating environmental issues With Geospatial Technology. Dordrecht, The Netherlands: Springer.

Manni R. (2012). Paleontological Museums and Geoethics. Ann Geophys 55(3):469–472.

Marceau, D.J. (1999). The scale issue in social and natural sciences. Canadian Journal of Remote Sensing. 25 (July), pp. 347–356.

Marchev, P., Kaiser-Rohrmeier, M., Heinrich, C., Ovtcharova, M., von Quadt, A., & Raicheva, R. (2005). 2: Hydrothermal ore deposits related to post-orogenic extensional magmatism and core complex formation: The Rhodope Massif of Bulgaria and Greece. Ore Geology Reviews, 27(1-4), 53-89.

Massonnet, D., Feigl, K. (1998). Radar interferometry and its’ application to changes in the earth’s surface. Rev. Geophys. 36 (4), pp. 441-500.

Massonnet, D., Rossi, M., Carmona, C., Adranga, F., Pelger, G., Feigl, K., Rabaut, T. (1993). The displacement field of the Landers earthquake mapped by radar interferometry. Nature, 364, pp. 138-142.

Mather, M.P. (1999). Computer Processing of Remotely-Sensed Images.UK: J. Wiley & Sons, 2nd edition p. 292.

Mather, P. (2011). Computer Processing of Remotely-Sensed Images: An Introduction.

McNulty A. E., 2000. Industrial Minerals in Antiquity: Melos in the Classical and Roman Periods. Unpubl. PhD. Thesis. Department of Archaeology and Division of Earth Sciences. University of Glasgow.

McFeeters, S.K. (1996). The Use of the Normalized Difference Water Index (NDWI) in the Delineation of Open Water Features. International Journal of Remote Sensing, 17, 1425-1432. http://dx.doi.org/10.1080/01431169608948714

Mendoza R., Rey J., Martínez J., Hidalgo M. C. (2022). Geological and Mining Heritage as a Driver of Development: The NE Sector of the Linares-La Carolina District

(Southeastern Spain), Geosciences, 12, 76. https:// doi.org / 10.3390/ geosciences12020076.

Miguel D., Brilha J., Alegret L., Arenillas I., Arz J., Gilabert V., Strani F.,· Valenciano A.,· Villas E., Azanza B., (2021). Linking geological heritage and geoethics with a particular emphasison palaeontological heritage: the new concept of “palaeontoethics”, Geoheritage https://doi.org/10.1007/s12371-021-00595-3.

Mohamed Abdel-Monem Sayed. (2018). Potential of 3d laser point cloud data usage for the tourism industry, 12th International Conference on Civil and Architecture Engineering, ICCAE-12-2018, Military Technical College Kobry El-Kobbah, Cairo, Egypt.

Mouratidis A., Ampatzidis D. (2019). European Digital Elevation Model Validation against Extensive Global Navigation Satellite Systems Data and Comparison with SRTM DEM and ASTER GDEM in Central Macedonia (Greece), ISPRS Int. J. Geo-Inf. 2019, 8, 108; doi:10.3390/ijgi8030108, MDPI.

Mouratidis A., Briole P., Katsambalos K. (2010). SRTM 3″ DEM (versions 1, 2, 3, 4) validation by means of extensive kinematic GPS measurements: a case study from North Greece, International Journal of Remote Sensing, 31:23,6205-6222,DOI:10.1080/01431160903401403.

National Geographic Society. (2018). Geo-education: essential preparation for an interconnected world. https://www.nationalgeographic.org/education/geo-education-essential-preparation-interconnected-world/.

National Geographic. (2020). About Geotourism. National Geographic, https://www.nationalgeographic.com/maps/geotourism/about/.

Nazarudd D.A. (2019). Selected geosites for geoheritage, geotourism, and geoconservation in Songkhla Province, Southern Thailand. Quaestiones Geographicae 38(1), Bogucki Wydawnictwo Naukowe, Poznań, pp. 161–177, ISSN 0137-477X, e ISSN 2081-6383.

Newsome D., Dowling R.K. (2010). Geotourism: The Tourism of Geology and Landscape. Goodfellow Publishers, Oxford, p.320.

Nieto, L.M. (2001). Geodiversidad: Propuesta de una definición integradora. Bol. Geológico Min. 112, 3–12.

Noszczyk T., Gawronek P. (2020). Remote Sensing and GIS for Environmental Analysis and Cultural Heritage, Remote Sens. 12, 3960; doi: 10.3390/rs12233960.

Ormeling, F. (2009). Technical Geography Core concepts in the mapping sciences. p. 482. ISBN 978-1-84826-960-6.

Osborne R.A.L. (2000). Geodiversity: Green geology in action Presidential address for 1999-2000. Proceedings of the Linnaean Society of New South Wales 122: 149-173.

Papadopoulou E.E., Papakostantinou A., Vasilakos C., Zouros N., Tataris G., Proestakis S., Soulakellis N. (2022). Scale issues for geoheritage 3D mapping: The case of

Lesvos Geopark, Greece, International Journal of Geoheritage and Parks 10 435–446, https://doi.org/10.1016/j.ijgeop.2022.08.006.

Papanikolaou D., Lekkas E., Mirkou M.R., Syskakis D. (1990). Geodynamic aspects during early Pliocene in Milos Island, Cyclades, Aegean Sea. Int. Earth Sciences Congress on the Aegean Region (IESCA), Izmir 1990, Abstracts p.237.

Parcharidis I., Gartzos E., Psomiadis E. (2001), Evaluation of remote sensing methods for the detection of hydrothermal alteration zones in Milos island, Greece

Payne A. (2009). Laser Scanning for Archaeology: A Guide to Good Practice.

Peppoloni S, Bilham N, Di Capua G. (2019). Contemporary geoethics within the geosciences. In: Bohle M (ed) Exploring geoethics: ethical implications, societal contexts, and professional obligations of the geosciences. Palgrave Pivot, pp. 25–7.

Peppoloni S., Di Capua G. (2014). The meaning of Geoethics. In: Wyss M. And Peppoloni S. (Eds), Geoethics: ethical challenges and case studies in Earth Science, 450 p., Elsevier, Waltham, Massachusetts, ISBN: 9780127999357.

Peppoloni S., Di Capua G. (2020). Geoethics as global ethics to face grand challenges for humanity. In: Di Capua G., Brobowsky P.T., Kieffer S.W., Palinkas C. (eds) Geoethics: status and future perspectives. Geological Society, London, Special Publications, 508, 1–17.

Peppoloni, S.; Di Capua, G. (2015). The meaning of geoethics. In Ethical Challenges and Case Studies in Earth Sciences; Wyss, M., Peppoloni, S., Eds.; Elsevier: Amsterdam, The Netherlands,; pp. 3–14.

Pérez-Aguilar, A.; Juliani, C.; de Barros, E.J.; Magalhães de Andrade, M.R.; de Oliveira, E.S.; Braga, D.d.A.; Santos, R.O., (2013). Archaeological gold mining structures from colonial period present in Guarulhos and Mairiporã, São Paulo State, Brazil, Geoheritage, 5, 87–105.

Pieraccini, M., Guidi, G., & Atzeni, C. (2001). 3D digitizing of cultural heritage. Journal of Cultural Heritage, 2(1), 63–70.

Pijet-Migόn E., Migόn P. (2022). Geoheritage and Cultural Heritage—A Review of Recurrent and Interlinked Themes, Geosciences 2022, 12, 98. https://doi.org/10.3390/geosciences12020098.

Poulos S.E., Ghionis G., Maroukian H. (2009). Sea‐level rise trends in the Attico–Cycladic region (Aegean Sea) during the last 5000 years. Geomorphology, 107(1–2):10‐17. doi: 10.1016/j.geomorph.2007.05.022.

Prosser C. (2019). Communities, Quarries and Geoheritage—Making the Connections, Geoheritage, https://doi.org/10.1007/s12371-019-00355-4.

Prosser, C. (2002a). Terms of endearment. Earth Heritage 17: 12-13.Joint Nature Conservation Committee, English Nature,Scottish Natural Heritage and the Countryside Council for Wales.

Prosser, C. (2002b). Also speaking the same language. Earth Heritage 18: 24-25. Joint Nature Conservation Committee, English Nature, Scottish Natural Heritage and the Countryside Council for Wales.

Rabeder, G., Tsoukala, E. (1990). Morphodynamic analysis of some cave-bear teeth from Petralona Cave (Chalkidiki, North-Greece). Beiträge zur Paläontologie von

Österrreich, 16: 103-109.

Rabus Β., Eineder M., Roth, A., Bamler, R. (2003). The shuttle radar topography mission—a new class of digital elevation models acquired by spaceborne radar, ISPRS Journal of Photogrammetry and Remote Sensing, Volume 57, Issue 4, Pages 241-262, ISSN 0924-2716, https://doi.org/10.1016/S0924-2716(02)001247 (https://www.sciencedirect.com/science/article/pii/S0924271602001247).

Rajyalakshmi, D., Raju, K.K., Varma, G.P.S. (2016). Taxonomy of Satellite Image and Validation Using Statistical Inference. 2016 IEEE 6th International Conference on Advanced Computing (IACC). pp. 352–361.

Ramakrishnan D., Bharti R. (2015). "Hyperspectral remote sensing and geological applications". Current Science: 879–891.

Regolini-Bissig G. (2010). Mapping geoheritage for interpretive purpose: definition and interdisciplinary approach. In: Regolini-Bissig G., Reynard E. (eds) Mapping Geoheritage, Géovisions, Geography Institute, Lausanne, 35. pp. 1–13.

Reynard E., Brilha J. (2018). Geoheritage- Assessment, Protection, and Management, Elsevier, ISBN: 978-0-12-809531-7.

Richards J.A. (1986). Remote Sensing Digital Image Analysis. An introduction, Springen-Verlag Berlin Heidelberg.

Richards, J. A & Jia, X., (2006). Remote Sensing Digital Image Analysis

Richards, J.A. (2013). Remote Sensing Digital Image Analysis. Fifth. Berlin, Heidelberg: Springer Berlin Heidelberg.

Risbøl O., Briese C., Doneus M., Nesbakken A. (2014). Monitoring cultural heritage by comparing DEMs derived from historical aerial photographs and airborne laser scanning, Elsevier, http://dx.doi.org/10.1016/j.culher.2014.04.002.

Rucker F. (2010). Eyes of the Army - U.S. Army Roadmap for UAS 2010-2035, U.S Army.

Santos I., Henriques R., Mariano G., Pereira D. (2018). Methodologies to Represent and Promote the Geoheritage using Unmanned Aerial Vehicle, Multimedia Technologies and Augmented Reality, Geoheritage, https://doi.org/10.1007/s12371-018-0305-0.

Sayre, N.F. (2005). Ecological and geographical scale. Progress in Human Geography. 3. pp. 276–290.

Schowengerdt, R.A. (2007). Remote Sensing: Models and Methods for Image Processing. 3rd Ed. Academic Press.

Semeniuk V. (1997). The linkage between biodiversity and geodiversity. In: R Eberhard (ed), Pattern & Processes: Towards a Regional Approach to National Estate assessment of geodiversity. Technical Series No. 2, Australian Heritage Commission & Environment Forest Taskforce, Environment Australia, Canberra, p 51 - 58.

Serrano-Juan Α., Vázquez-Suñè E., Monserrat O., Crosetto M., Hoffmann C., Ledesma A., Criollo R., Pujades E., Velasco V., Garcia-Gil A., Alcaraz M. (2016). Gb-SAR interferometry displacement measurements during dewatering in construction works. Case of La Sagrera railway station in Barcelona, Spain, Elsevier, http://dx.doi.org/10.1016/j.enggeo.2016.02.014.

Shahbaz, M., Guergachi, A., Noreen, A., Shaheen, M. (2012). Classification by Object Recognition in Satellite Images by using Data Mining. Proceedings of the World Congress on Engineering.

Sharples C. (2002). Concepts and principles of geoconservation. Tasmanian Parks & Wildlife Service, Hobart.

Sharples, C. (1993). A Methodology for the iden9tification of significant landforms and geological sites for geoconservation purposes. Report to Forestry Commission Tasmania, Hobart, Tasmania.

Sharples, C. (1995). Geoconservation in forest management principles and procedures. Tasforests 7: 37-50.

Sheng, G., Yang, W., Xu, T. & Sun, H. (2011). High-resolution satellite scene classification using a sparse coding based multiple feature combination. International Journal of Remote Sensing. 33 (8). pp. 2395–2412.

Sheppard, E. & McMaster, R.B. (2004). Scale and geographic inquiry: Nature, society, and method. Blackwell Publishing.

Shishido, H., Ito, Y., Kawamura, Y., Matsui, T., Morishima, A., & Kitahara, I., (2017). Proactive preservation of World Heritage by crowdsourcing and 3D reconstruction technology. Paper presented at the 2017 IEEE, International Conference on Big Data (Big Data), Boston.

Skidmore, A. (2003). Environmental Modelling with GIS and Remote Sensing. Available at: https://www.taylorfrancis.com/books/e/9780203302217.

Slater P.N. (1980). Remote Sensing: Optics and Optical System. Addison - Wesley: Reading Mass.

Sotiriadis L., Psilovikos A., Astaras Th. (1972). Origin and formation of some characteristic geomorphological occurrences in the tectonic valley of Langada - Volvi.''Nymphopetres''.

Sousa J., Ruiz A.,Hanssen R., Bastos L., Gil A., Galindo-Zaldívar J., Sanz de Galdeano C., 2009, PS-InSAR processing methodologies in the detection of field surface deformation—Study of the Granada basin (Central Betic Cordilleras, southern Spain),Elsevier Ltd.,Journal of Geodynamics 49 (2010) 181–189,doi:10.1016/j.jog.2009.12.002

Spyrou E., Triantaphyllou M., Tsourou T.,Vassilakis E., Asimakopoulos C., Konsolaki A., Markakis D., Marketou-Galari D., Skentos A. (2022). Assessment of Geological Heritage Sites and Their Significance for Geotouristic Exploitation: The Case of Lefkas, Meganisi, Kefalonia and Ithaki Islands, Ionian Sea, Greece, Geosciences,12, 55.

https:// doi.org/10.3390/geosciences12020055.

Stevens C. (1994). Defining geological conservation. Keynote Address In: D OHalloran, C., Green, M., Harley, M., Stanley, J. Knil (eds), Geological and Landscape Conservation. Proceedings of the Malvern International Conference 1993. Geological Society, London, UK.

Subramanian S. (2001). Evaluation of digital elevation models created from different satellite images, India.

Szepesi J., Ésik Z, Soós I., Németh B., Sütő L., Novák T., Harangi S., Lukács R., (2020). Identification of Geoheritage Elements in a Cultural Landscape: a Case Study from

Tokaj Mts, Hungary, The European Association for Conservation of the Geological Heritage, https://doi.org/10.1007/s12371-020-00516-w.

Tapete D. (2016). Trends and perspectives of space-borne SAR remote sensing for archaeological landscape and cultural heritage applications, Elsevier, http://dx.doi.org/10.1016/j.jasrep.2016.07.017.

Tapete D. (2018). Remote Sensing and Geosciences for Archaeology, Geosciences, 8, 41; doi:10.3390/geosciences8020041.

Themistocleous Κ., Agapiou Α., Cuca Β., Hadjimitsis D. (2015). Unmanned Aerial Systems And Spectroscopy For Remote Sensing applications In Archaeology, The

International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XL-7/W3,36th International Symposium on Remote Sensing of

Environment, 11–15 May 2015, Berlin, Germany, doi:10.5194/isprsarchives-XL-7-W3-1419-2015.

Theodosiou Ir. (2010). Designation Of Geosites- Proposals For Geoparks In Greece, Bulletin of the Geological Society of Greece, Vol. 43, Proceedings of the 12th International Congress Patras, May.

Thomas F.M. (2016). New keywords in the geosciences– some conceptual and scientific issues, Revista do Instituto Geológico, São Paulo, 37 (1), 1-12.

Tičar J., Komac B., Zorn M., Ferk M., Hrvatin M., Ciglič R. (2017). From urban geodiversity to geoheritage: The case of Ljubljana (Slovenia), Quaestiones Geographicae 36(3) doi: 10.1515/quageo- 2017-0023 ISSN 0137-477X.

Tsirambides A., Filippidis A. (2016). Gold Metallogeny of the Servomacedonian - Rhodope metallogenic belt (SRMB), Bulletin of the Geological Society of Greece, vol. L, p. 2037-2046, Proceedings of the 14 th International Congress, Thessaloniki,

Tsoukala, E. (1989). Contribution to the study of the Pleistocene fauna of large mammals (Carnivora, Perissodactyla, Artiodactyla) from Petralona Cave, Chalkidiki (N. Greece). Ph. D. Thesis, Scientific Annals, School of Geology, Aristotle University, 8: 1-360, I-LXII plates, Thessaloniki.

Tucci G., Bonora V., Conti A., Fiorini L. (2017). High-Quality 3d Models And Their Use In A Cultural Heritage Conservation Project, The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLII-2/W5, 26th International CIPA Symposium, 28 August–01 September 2017, Ottawa,

Canada, doi:10.5194/isprs-archives-XLII-2-W5-687-2017.

Tzouvaras M., Kouhartsiouk D., Agapiou A., Danezis C., Hadjimitsis D. (2019). The Use of Sentinel-1 Synthetic Aperture Radar (SAR)Images and Open-Source Software for Cultural Heritage: An Example from Paphos Area in Cyprus for Mapping Landscape Changes after a Magnitude Earthquake, Remote Sens. 11, 1766; doi: 10.3390/rs11151766.

Vaiphasa, C., Piamduaytham, S., Vaiphasa, T. & Skidmore, A.K. (2011). A normalized difference vegetation index (NDVI) time-series of idle agriculture lands: A preliminary study. Engineering Journal. 15 (1). pp. 9–16.

Vlachopoulos N.,Voudouris P. (2022). Preservation of the Geoheritage and Mining Heritage of Serifos Island, Greece: Geotourism Perspectives in a Potential New Global Unesco Geopark, Geosciences, MDPI, 12, 127. https://doi.org/ 10.3390/geosciences12030127.

Voudouris P., Mavrogonatos C., Melfos V., Alfieris D., Stamatakis M. (2014), Alunite occurrences in Greece: Geological-Mineralogical constraints and exploitation, Coastal Landscapes, Mining activities & Preservation of Cultural Heritage, 17-20/09/2014, Milos island

Wang P., Xing C., Pan X., Zhou X., Shi B. (2021). Microdeformation monitoring by permanent scatterer GB-SAR interferometry based on image subset series with short temporal baselines: The Geheyan Dam case study, Elsevier, https://doi.org/10.1016/j.measurement.2021.109944.

Wang, K., Xiang, W., Guo, X. & Liu, J. (2012). Remote Sensing of Forestry Studies. In: Global Perspectives on Sustainable Forest Management. InTech.

Wang, Y., Wu, F., Li, X., & Chen, L. (2019). Geotourism, geoconservation, and geodiversity along the belt and road: A case study of Dunhuang UNESCO Global Geopark in

China. Proceedings of the Geologists' Association, 130(2), 232–241.

Warner, T.A., Nellis, M.D. & Foody, G.M. (2009). Remote Sensing Scale and Data Selection Issues. In: The SAGE Handbook of Remote Sensing. Oliver’s Yard, 55 City Road, London EC1Y 1SP United Kingdom: SAGE Publications Ltd, pp. 3–17.

Williams M., McHenry M. (2020). The Increasing Need for Geographical Information Technology (GIT) Tools in Geoconservation and Geotourism, Geoconservation Research,

Volume 3 / Issue 1 / pages (17-32) e-ISSN: 2645-4661 p-ISSN: 2588-7343.

Wilson A. (2022). The use of remote sensing and digital tools for cultural heritage management and archaeological research, LevantThe Journal of the Council for British Research in the Levant, https://doi.org/10.1080/00758914.2022.2051901.

Wiseman J., El-Baz F., (2007). Remote Sensing in Archaeology, Springer Science, e-ISBN 10 0-387-44455-6.

Woodcock, C. E. (2008). Free access to Landsat imagery, Science 320: 1011–1012. doi:10.1126/science.320.5879.1011a.

Wu, H. & Li, Z.L. (2009). Scale issues in remote sensing: A review on analysis, processing and modeling. Sensors. 9 (3). pp. 1768–1793.

Wu, J. & Li, H. (2006). Concepts of Scale and Scaling. In: J. Wu, K. B. Jones, H. Li, & O. L. Loucks (eds.). Scaling and Uncertainty Analysis in Ecology: Methods and Applications.Springer Science & Business Media.

Wulder, M. A., Masek, J. G., Cohen, W. B., Loveland, T. R., and Woodcock, C. E. (2012). Opening the archive: How free data has enabled the science and monitoring promise of Landsat. Remote Sensing of Environment 122: 2–10. Doi: 10.1016/j. rse.2012.01.010.

Yu, L., Liang, L., Wang, J., Zhao, Y., Cheng, Q., Hu, L., Liu, S., Yu, L., Wang, X., Zhu, P., Li, X., Xu, Y., Li, C., Fu, W., Li, X., Li, W., Liu, C., Cong, N., Zhang, H., Sun, F., Bi, X.,

Xin, Q., Li, D., Yan, D., Zhu, Z., Goodchild, M.F. & Gong, P. (2014). Meta-discoveries from a synthesis of satellite-based land-cover mapping research. International Journal of Remote Sensing. 35 (13). p.pp. 4573–4588.

Yusry M., Simon N., Unjah T. (2018). Geodiversity and geoheritage assessment in Hulu Langat district, Selangor, Malaysia, Geo Journal of Tourism and Geosites, Year XI, vol. 23, no. 3, 2018, p.861-872,ISSN 2065-0817, E-ISSN 2065-1198.

Zafeiropoulos G., Drinia H., Antonarakou A., Zouros N. (2021) From Geoheritage to Geoeducation, Geoethics and Geotourism: A Critical Evaluation of the Greek Region, Geosciences,11, 381. https:// doi.org/10.3390/geosciences11090381.

Zagorchev I. Nakov R. (1998). Geological Heritage of Europe (Special Issue). Geologica Balcanica 28. 3-4.

Zebker, H.A., Goldstein, R.M. (1986). Topographic mapping from interferometry synthetic aperture radar observations, J. Geophys. Res., 91, (B5), pp. 4993-4999.

Zhao, L. Hong, H. Liu, J. Fang, Q. Yao, Y. Tan, W. Yin, K. Wang, C. Chen, M. Algeo, T. J. (2018). Assessing the utility of visible-to-shortwave infrared reflectance spectroscopy for analysis of soil weathering intensity and paleoclimate reconstruction, Palaeogeography, Palaeoclimatology, Palaeoecology. 512: 80–94. doi:10.1016/j.palaeo.2017.07.007. S2CID 133726583.

Zhe Zhu, Shi Qiu, Binbin He, and Chengbin Deng. (2018). Cloud and Cloud Shadow Detection for Landsat Images: The Fundamental Basis for Analyzing Landsat Time Series, DOI: 10.1201/9781315166636-1:https://www.researchgate.net/publication/324975294.

Zhou X., Kuiper K., Wijbrans J., Boehm K., Vroon P., (2021) Eruptive history and 40Ar/39Ar geochronology of the Milos volcanic field, Greece, Geochronology, EGU

Zhu, X. (2016). GIS for environmental applications: a practical approach. London; New York, NY: Routledge.

Zouros N. (2004). The European Geoparks Network. Geological heritage protection and local development. Episodes 27(3):165–171.

Zouros N. (2005). Assessment, protection, and promotion of geomorphological and geological sites in the Aegean area, Greece, p. 227-234, https://doi.org/10.4000/geomorphologie.398, Open Edition Journals.

Zouros N. (2007). Geomorphosite assessment and management in protected areas of Greece. The case of the Lesvos Island coastal geomorphosites. Geogr Helv 62(3):169–180.

Zouros N., Valiakos I. (2010). Geoparks Management And Assessment, Bulletin of the Geological Society of Greece, Vol. 43, Proceedings of the 12th International Congress Patras, May.

Zouros, N., Valiakos, I. (2008). Geosites assessment and management in protected areas of Greece. The case of the Lesvos Petrified Forest Geopark. Proceedings of the 3rd International UNESCO Conference on Geoparks, Osnabrück, Germany.

ΒΙΒΛΙΟΓΡΑΦΙΑ ΕΛΛΗΝΙΚΗ

Αλεξάκης Δ. (2009). Η συμβολή της γεωμορφολογίας με τη βοήθεια της Τηλεπισκόπησης και των Γεωγραφικών Συστημάτων Πληροφοριών στη Χαρτογράφηση αρχαιολογικών θέσεων, διδακτορική διατριβή, Τομέας Φυσικής και Περιβαλλοντικής Γεωγραφίας, Τμήμα Γεωλογίας, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης

Αποσπόρης Π. (2020). Το Βιβλίο των DRONES, Ολοκληρωμένος οδηγός για τα συστήματα μη επανδρωμέωνων αεροσκαφών, Εκδόσεις Παπαζήση ΑΕΒΕ.

Αστάρας Θ. (2011). Τηλεπισκόπηση - Φωτοερμηνεία στις Γεωεπιστήμες, εκδόσεις Γκιούρδας Β., ISBN-13: 9789603879039.

Αστάρας, Θ., Οικονομίδης, Δ., Μουρατίδης, Α. (2007). Ψηφιακή Χαρτογραφία και Γεωγραφικά Συστήματα Πληροφοριών (G.I.S.), διδακτικές σημειώσεις, Τμήμα Γεωλογίας, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης

Βαλιάκος Η. (2018). Γεωγραφία, Αξιολόγηση και Διαχείριση Γεώτοπων της Ελλάδας, Διδακτορική Διατριβή, Πανεπιστήμιο Αιγαίου, Σχολή κοινωνικών επιστημών, Τμήμα Γεωγραφίας, Μυτιλήνη.

Βουγιουκαλάκης Γ. (1992). «Έκθεση ηφαιστειολογικών και τεκτονικών παρατηρήσεων στη νήσο Μήλο για το σεισμό της 20/2/92», Ινστιτούτο Γεωλογικών και Μεταλλευτικών Ερευνών, Αθήνα.

Βαλιάκος Η., 2018, Γεωγραφία, Αξιολόγηση και Διαχείριση Γεώτοπων της Ελλάδας, Διδακτορική Διατριβή, Πανεπιστήμιο Αιγαίου, Σχολή κοινωνικών επιστημών, Τμήμα Γεωγραφίας, Μυτιλήνη

Βελιτζέλος Ε., Μουντράκης Δ., Ζούρος Ν., Σουλακέλης Ν., (2002), Ατλαντας των Γεωλογικών μνημείων του Αιγαίου, Υπουργείο Αιγαίου

Βουγιουκαλάκης Γ. (2005). Στα γαλάζια ηφαίστεια. ΣΑΝΤΟΡΙΝΗ, Δημοτική Επιχείρηση Πολιτιστικής και Τουριστικής Ανάπτυξης Δήμου Θήρας, Ινστιτούτο μελέτης και παρακολούθησης ηφαιστείου Σαντορίνης.

Βουγιουκαλάκης Γ., 1992, «Έκθεση ηφαιστειολογικών και τεκτονικών παρατηρήσεων στη νήσο Μήλο για το σεισμό της 20/2/92», Ινστιτούτο Γεωλογικών και Μεταλλευτικών Ερευνών, Αθήνα.

Δρακάτου Μ.Λ., Γαλάνη Α., Ισαάκ Π. (2017). Ενίσχυση του ενδιαφέροντος των μαθητών για την Τηλεπισκόπηση και τις δορυφορικές εικόνες μέσα από τη μη τυπική εκπαίδευση, Πρακτικά Εργασιών 5ου Πανελλήνιου Συνεδρίου «Ένταξη και Χρήση των ΤΠΕ στην Εκπαιδευτική Διαδικασία», σ. 4-14, Ανώτατη Σχολή Παιδαγωγικής &

Τεχνολογικής Εκπαίδευσης, 21-23 Απριλίου 2017.ISSN 2529-0924, ISBN 978-618-83186-0-1.

Ζούρος Ν., Βαλιάκος Η. (2007). Αξιολόγηση και Διαχείριση Γεωτόπων, 8ο Πανελλήνιο Γεωγραφικό Συνέδριο, Αθήνα, 4 – 7 Οκτωβρίου 2007.

Ι.Γ.Μ.Ε. Περιοδική Έκδοση, (2011). Η Συμβολή του Ινστιτούτου της Βιώσιμης και Ανταγωνιστικής Ανάπτυξης της Ελλάδας, Τεύχος 12, ISSN:1791-2210.

Κάβουρας, Μ., Δάρρα, Α., Κόκλα, Μ., Κονταξάκη, Σ., Πανόπουλος, Γ., & Τομαή, Ε. (2016). Επιστήμη Γεωγραφικής Πληροφορίας - Ολοκληρωμένη Προσέγγιση και Ειδικά Θέματα. Αθήνα: Σύνδεσμος Ελληνικών Ακαδημαϊκών Βιβλιοθηκών.

Καρτάλης Κ., Φείδας Χ. (2019). Αρχές και εφαρμογές Δορυφορικής Τηλεπισκόπησης, εκδόσεις Τζιόλα.

Καρτάλης, Κ., Φειδάς, Χ. (2006). Αρχές και εφαρμογές Δορυφορικής Τηλεπισκόπησης, εκδόσεις Γκιούρδας.

Κοντόση Κ., (2007), Τα GIS στην εκπαιδευτική διαδικασία. Δυνατότητες και προοπτικές χρησιμοποίησής τους στη διδασκαλία των Φυσικών Επιστημών, 2ο Εκπαιδευτικό Συνέδριο: Γλώσσα, Σκέψη και Πράξη στην Εκπαίδευση, Ιωάννινα, 19-21/10/2007

Κουτρουμπά Δ. (2018). Τα ορυχεία της Μήλου: Η καταγραφή μιας διαχρονικής βιομηχανικής δραστηριότητας, Ερευνητική Εργασία, Τμήμα Αρχιτεκτόνων Μηχανικών, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης.

Κουφός Γ., Τσουκαλά Ε. (2007). Πετράλωνα ένα σπήλαιο, μια προϊστορία, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης.

Λόζιος, Σ., Σούκης, K., Αντωνίου, Β. (2015). Τοπογραφικοί χάρτες και μορφολογικές δομές αναγλύφου. Γεωλογική χαρτογράφηση και ασκήσεις υπαίθρου, Ανοικτές Ακαδημαϊκές Εκδόσεις Κάλλιπος, https://hdl.handle.net/11419/1269.

Μέλφος Β. (2009) Ο Πράσινος Θεσσαλικός Λίθος και τα λατομεία της Χασάμπαλης, Δήμος Νέσσωνος ΔΗ.ΚΕ.ΔΗ.Ν, ISBN: 978-960-6700-38-5.

Μερτίκας, Σ.Π. (1999) Τηλεπισκόπηση και Ψηφιακή ανάλυση εικόνας, εκδόσεις ΙΩΝ.

Μουρατίδης Α. (2010). Συμβολή της υποστηριζόμενης από GPS και GIS διαστημικής Τηλεπισκόπησης στη μορφοτεκτονική έρευνα της Κεντρικής Μακεδονίας, Διδακτορική Διατριβή, Τμήμα Γεωλογίας, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης.

Νικολάου Μ., (2005). Ορυκτά, Πετρώματα και Πολιτισμός, Μουσείο Γουλανδρή Φυσικής Ιστορίας

Οικονόμου Α. (2019). Πολιτιστική Κληρονομιά, Υλική Και Άυλη: Δυο Όψεις Του Ίδιου Νομίσματος; Το Παράδειγμα Της Αγροδιατροφικής Παράδοσης, https://www.academia.edu/45025389/.

Παπαδοπούλου Α. (2014). Ανάκτηση, Αξιοποίηση, Αποκατάσταση Τοπίων Εκμετάλλευσης Ορυκτού Πλούτου, Διδακτορική Διατριβή, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης, Τμήμα Αρχιτεκτόνων Μηχανικών, Πολυτεχνική Σχόλη Τομέας Αρχιτεκτονικού & Αστικού Σχεδιασμού.

Παπανικολάου Μ., Παπανικολάου Δ., Βασιλάκης Ε. (2011). Μεταβολές της Στάθμης της Θάλασσας και Επιπτώσεις στις Ακτές. Επιτροπή Μελέτης Επιπτώσεων Κλιματικής Αλλαγής, Τράπεζα της Ελλάδος.

Παρχαρίδης Ι. (2015). Αρχές δορυφορικής Τηλεπισκόπησης, Θεωρία και εφαρμογές, Σύνδεσμος Ελληνικών Ακαδημαϊκών Βιβλιοθηκών, ISBN: 978-960-603-443-5.

Πατώνης Φ., Σημειώσεις Μαθήματος Σχεδίου- Απεικόνιση βασικών στοιχείων υποβάθρου τοπογραφικού διαγράμματος, ακαδημαϊκό έτος 2014-2015, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης, Πολυτεχνική Σχόλη Τμήμα Αγρονόμων & Τοπογράφων Μηχανικών, Τομέας Κτηματολογίου, Φωτογραμμετρίας και Χαρτογραφίας.

Παυλίδης Σ., (2022). Η δημιουργία του Αιγαίου, Γερμανός

Ποϊραζίδης Κ., Βούλγαρης, Μ Δ, Κεφαλάς, Γ, Λορίλια, Ρ Σ. (2013). Βασικές Αρχές Της Τηλεπισκόπησης Επιμέλεια-Απόδοση Στα Ελληνικά, e-book.

Σημαιάκης Κ. (1985).Γεωθερμική έρευνα νησιώτικου συμπλέγματος Μήλου υπέρ Δ.Ε.Η. – Συμπεράσματα νεοτεκτονικής μελέτης, Ινστιτούτο Γεωλογικών και Μεταλλευτικών Ερευνών, Αθήνα.

Σημαιάκης Κ., (1985). Νεοτεκτονική εξέλιξη νησιώτικου συμπλέγματος Μήλου, Ινστιτούτο Γεωλογικών και Μεταλλευτικών Ερευνών, Αθήνα.

Σουλακέλλης Ν., Ζούρος Ν., (1998), Ψηφιακός χάρτης γεωλογικών μνημείων της Λέσβου με την χρήση ΓΣΠ. 3ο Διεθνές Συμπόσιο «Διαχείριση προστατευόμενων περιοχών - Μνημεία της Φύσης»

Σούλιος Γ. (2004). Γενική Υδρογεωλογία, Τρίτος Τόμος, ΣΤ. Αποθέματα και διαχείριση του υπόγειου νερού, εκδόσεις Αδερφών Κυριακίδη Α.Ε., ISBN 960-343-784-0.

Σταμούλη Μ., Τζούρα Α. (2022). Τρισδιάστατη αποτύπωση του γεωλογικού πάρκου της Νυμφόπετρας, Διπλωματική Εργασία, Πολυτεχνική Σχολή, Τμήμα Αγρονόμων Τοπογράφων Μηχανικών, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης

Σταρίδας Σ., Γαλανάκης Δ., (2016), Γεωδιαδρομές στη Μήλο, Διεύθυνση Γενικής Γεωλογίας και Γεωλογικών Χαρτογραφήσεων, Ινστιτούτο Γεωλογικών & Μεταλλευτικών Ερευνών

Τσιούκας Β. (2009). Χρήση νέων τεχνολογιών στην 3D αποτύπωση μνημείων και χώρων, σημειώσεις σεμιναρίου ΤΕΕ, Ξάνθη.

Τσόκας Γρηγόρης Ν. (1985). Γεωφυσική διασκόπηση των νησιών Μήλος και Κίμωλος, Επιστημονική Επετηρίδα της Σχολής Θετικών Επιστημών Α.Π.Θ., παράρτημα αριθμ. 50 του 23ου τόμου, σ. 12-21, σ. 108-126.

Τσούλος Λ., Σκοπελίτη Α., Στάμου Λ. (2015). Χαρτογραφική Σύνθεση και Απόδοση σε Ψηφιακό Περιβάλλον, Σύνδεσμος Ελληνικών Ακαδημαϊκών Βιβλιοθηκων, ISBN: 978-960-603-271-4.

Φαλτσέτα Σ. (1997). Το Γεωπεριβάλλον στο Χωροταξικό Σχεδιασμό: Μεθοδολογία Προσέγγισης. Μεταπτυχιακή Διπλωματική εργασία. Τμήμα Αστικής και Περιφερειακής Ανάπτυξης. Πάντειος. Σελ. 9,33,21.

Φλιούκα Π. (2013). Τηλεκατευθυνόμενα μη επανδρωμένα συστήματα λήψης εικόνων για τη θεματική και μετρητική τεκμηρίωση του αστικού και περιαστικού χώρου, Πολυτεχνική Σχολή, Τμήμα Μηχανικών Χωροταξίας και Ανάπτυξης, Αριστοτελείου Πανεπιστημίου Θεσσαλονίκης.

Φυτίκας Μ., Ανδρίτσος Νικόλαος Β., (2004). «Γεωθερμία», εκδόσεις ΤΖΙΟΛΑ, Θεσσαλονίκη.

Φυτίκας Μ., (1977). Γεωλογική και Γεωθερμική μελέτη της νήσου Μήλου, Διδακτορική Διατριβή, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης

Χαλκιάς, Χ. (2001). Ψηφιακά Μοντέλα Εδάφους, Αθήνα: Πανεπιστημιακές Σημειώσεις.

Ψιλοβίκος Α., (1977). Παλαιογεωγραφική εξέλιξη της λεκάνης και της λίμνης της Μυγδοίας (ΛΑγκαδα-Βόλβη), Διδακτορική Διατριβή, Αριστοτέλειο Πανεπιστήμιο Θεσσαλονίκης

ΙΣΤΟΣΕΛΙΔΕΣ

URL 01 www.spilaio-perama.gr 20-08-23

URL 02 kefaloniageopark.gr 10-09-23

URL 03 igmegeoheritage.weebly.com/ 10-12-23

URL 04 www.earthdata.nasa.gov/learn/backgrounders/passive-sensors

URL 05 sentinels.copernicus.eu /web/ sentinel/ missions

URL 06 www.usgs.gov

URL 07 antiparosroutes.com 10-09-23

URL 08 lesvosmuseum.gr 10-09-23

URL 09 lemnosgeomonuments.gr 10-09-23

URL 10 miloterranean.gr 10-09-23

URL 11 topoguide.gr 10-09-23

URL 12 nisyrosgeopark.gr 10-09-23

URL 13 sitia-geopark.gr 10-09-23

URL 14 www.psiloritisgeopark.gr 10-09-23

URL 15 geoparklavreotiki.gr 10-09-23

URL 16 whc.unesco.org/en/list/1695 15-12-23

URL 17 whc.unesco.org/en/statesparties/GR/ 15-12-23

URL 18 www.eagme.gr/site/services

URL 19 www.discovergreece.com/cyclades/milos 25-11-23

URL 20 www.dji.com/gr/mavic-mini

URL 21 aca-apac.com/my/products/product-detail/blk360

URL 22 3dtarget.it

URL 23 ultimaker.com

URL 24 structure.io

URL 25 intelrealsense.com

URL 26 climate.copernicus.eu/climate-indicators/sea-level 30-10-23

URL 27 www.usgs.gov/landsat-missions/landsat-collection-2-level-2-science-products

URL 28 gis.web.auth.gr

URL 29 gis.web.auth.gr/Webmaps/Geoheritage_171023_v3/index.html

URL 30 teachablemath.com/cut-shape-area-perimeter/

URL 31 education.nationalgeographic.org

URL 32 www.isprs.org

URL 33 http://www.hellenicgeoparks.gr/

URL 34 https://www.europeangeoparks.org/

URL 35 http://www.globalgeopark.org

URL 36 http://www.mfi-miliasgrevenon.gr

URL 37 https://www.milosminingmuseum.com