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Showing 131 to 140 of 140 (0.366 seconds)Spelling suggestions: "subject:"geochemical"" "subject:"geochemically""
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Paläoökologische und geochemische Studien auf Schwamm-Mikroinkrustrierer- Gemeinschaften ausgewählter Cipit Kalke aus der St. Cassian Formation (Unterkarn, Obertrias) von der Dolomiten, Nordostitalien / Paleoecological and geochemical studies on sponge/microencruster -bearing communities contained in selected Cipit Boulders from the St. Cassian Formation (Lower Carnian, Upper Triassic) of the Dolomites, Northeastern ItalySánchez Beristain, Juan Francisco 29 November 2010 (has links)
No description available.
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| 132 |
Rezente und subfossile Mikrobialithe westaustralischer Salzseen / Recent and subfossil microbialites from westaustralian salt lakesCaselmann, Meike 20 May 2005 (has links)
No description available.
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Geological and mineralogical investigation of hydrothermal fluid discharge features at the sea bottom of Panarea, ItalyStanulla, Richard 01 September 2021 (has links)
The thesis presents research on recent hydrothermal discharge features in a shallow marine hydrothermal system. It aims to clarify their occurrence, genesis, and preservation potential. A facies model is developed, being based on the processes involved in the formation and the prevailing lithofacies. It describes six major groups: channels, fractures, tubes, cones, bowls, and lineaments. Each of these groups subdivides into numerous facies types according to the cements or mineral precipitates prevailing. To clarify the rather complex formation processes of hydrothermal discharge features, genetic models for each facies are proposed. An integrated evolutionary model is developed considering the temporal evolution of the major types of hydrothermal discharge features in the Panarea system and their preservation potential. Confirming presumptions of former, preliminary data, the first documentation of secure paleo-evidences of such hydrothermal discharge features is presented.:1. Introduction ....11
1.1. Preamble .....11
1.2. Research questions, objectives, and hypotheses ......................................... 12
2. State of research - seafloor hydrothermal systems ................................ 15
2.1. Hydrothermal deposits in general ................................................................. 15
2.2. Deep-sea environments ............................................................................... 16
2.3. Shallow-water systems and their preservation potential ............................... 17
3. Panarea Island - the area of investigation ................................................ 20
3.1. The hydrothermal system of Panarea Island ................................................ 20
3.2. Fluid discharge features in Panarea ............................................................. 30
3.3. Study sites .................................................................................................... 34
4. Materials and methods ............................................................................... 40
4.1. Underwater research .................................................................................... 40
4.2. Field methods ............................................................................................... 41
4.3. Laboratory methods ..................................................................................... 44
5. Results ........................................................................................................ 47
5.1. Prevailing lithologies ..................................................................................... 47
5.1.1. Hardrocks ..................................................................................................... 47
5.1.2. Sedimentary rocks ........................................................................................ 51
5.1.3. Sediments .................................................................................................... 54
5.1.4. Cements ....................................................................................................... 58
5.2. Underwater investigation sites and findings ................................................. 66
HYDROTHERMAL FLUID DISCHARGE FEATURES IN PANAREA, ITALY PAGE 10 | 174
5.2.1. Area 26 ......................................................................................................... 66
5.2.2. Basiluzzo ...................................................................................................... 75
5.2.3. Black Point ................................................................................................... 77
5.2.4. Bottaro North ................................................................................................ 79
5.2.5. Bottaro West ................................................................................................. 81
5.2.6. Cave ............................................................................................................. 84
5.2.7. Fumarolic Field ............................................................................................. 87
5.2.8. Hot Lake ....................................................................................................... 89
5.2.9. La Calcara .................................................................................................... 92
5.2.10. Point 21 ........................................................................................................ 98
5.2.11. Subaerial locations ..................................................................................... 100
5.3. Summarizing tables .................................................................................... 104
6. Interpretation ............................................................................................ 106
6.1. Discharge features and secondary processes ............................................ 106
6.1.1. Complex genesis and development of discharge features and their
occurrence throughout the system ............................................................. 119
6.1.1.1. Cones, bowls, and lineament structures ..................................................... 119
6.1.1.2. Tubes ......................................................................................................... 128
6.2. Preservation potential and paleo-record ..................................................... 138
7. Conclusion and Discussion .................................................................... 141
7.1. General context of the formation of hydrothermal discharge features in
Panarea ...................................................................................................... 141
7.2. Evolution of hydrothermal discharge features in Panarea .......................... 142
7.3. Comprehensive summary ........................................................................... 145
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Minerogeny of the Pan-African Volta Basin of GhanaBoamah, Kwame 04 March 2017 (has links)
Within the framework of this research, the complex geological history of the Pan African-Volta basin has been systematically reconstructed. Based on a broad review of literature and new data, 5 stages of geological-tectonic development have been identified. For the first time a systematic review of the mineral potential of the Pan-African Volta Basin was executed. Known and potentially existing mineralization have been related to the geotectonic history and metallogenetic conclusions have been drawn.
Based on the findings of this research, the folded thrust belt located at the eastern rim of the Volta basin has been identified as the most prospective area for the ultramafic rocks with chromite, nickel mineralization and PGEs, hydrothermal gold and banded iron formation (BIF) but this will require further work.:Table of contents
Table of contents iii
List of tables v
List of figures 1
Introduction 5
Summary of work done 6
Acknowledgements 6
1 In the Geology and regional geotectonic development of the West African Shield 7
1.1 Introduction 7
1.2 The basement of the Proterozoic sedimentary platform cover 9
1.3 Connection of West African Shield to Brazil 10
1.4 The Neoproterozoic sedimentary sequence and the extent of the Volta Basin 13
1.4.1 Introduction 13
1.4.2 The Neoproterozoic Sedimentary Sequence 15
1.5 The Pan-African Mobile Belt 23
1.5.1 The Buem Fold and thrust belt 23
1.5.2 New defined units 30
1.6 Interpretation of the deep structure of the Volta Basin 35
1.7 Metallic Minerals 37
1.7.1 Introduction 37
1.7.2 Iron (Fe) 39
1.7.3 Aluminium (Al) 46
1.7.4 Manganese (Mn) 50
1.7.5 Lead (Pb) 52
1.7.6 Copper (Cu) 55
1.7.7 Mineralisation related to ultramafic rocks 57
1.7.8 Gold (Au) 69
1.7.9 Tantalum (Ta) 72
1.7.10 Zirconium (Zr) 73
1.7.11 Heavy minerals in sands of Paleochannels 76
1.8 Non-metallic minerals 83
1.8.1 Introduction 83
1.8.2 Limestone (CaCO3) 84
1.8.3 Magnesite (MgCO3) 91
1.8.4 Barite (BaSO4) 93
1.8.5 Diamonds 97
1.8.6 Bitumen 100
1.9 Mineral Prediction with advangeo® Prediction Software 102
2 Minerogeny 109
2.1 Mineralisation controls and indicators 109
2.1.1 Geochemical Properties of selected stratigraphic units 109
2.1.2 Intrusive rocks 114
2.1.3 Volcanic rocks 118
2.1.4 Fault structural controls 119
2.1.5 Reactive Rocks 121
2.1.6 Other sedimentary controls: placers and paleoplacers 122
2.1.7 Laterites 122
2.1.8 Control of diamond occurrences 132
2.2 Key stages of metallogenic development 132
3 Discussion and recommendations 136
3.1 Recommendations 138
4 List of References 139
5 Appendices 144
5.1.1 Sample G113RK1 144
5.1.2 Sample G109RK1 145
5.1.3 Sample G116RK1 147
5.1.4 Sample G121RK1 149
5.1.5 Sample G121RK2 151
5.1.6 Sample G121RK3 152
5.1.7 Sample G131RK1 154
5.1.8 Sample G144RK2 155
5.1.9 Sample G145RK1 156
5.1.10 Sample G147RK1 157
5.2 Thin Sections 159
5.3 Deep drilling Data 174
5.4 Geophysical Datasets 176
5.5 Geochemical properties of volcanic rocks 181
5.6 Regional Geochemical Datasets (MSSP) 186
5.6.1 Methodology of data processing 188
5.7 Geochemical analysis – Electronic Dump 190
5.8 Geochemical properties of selected geo-tectonic units 190
5.8.1 Epicratonic basin 190
5.8.2 Foreland Basin 195
5.8.3 Thrusted continental margin 202
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Magmatic-Hydrothermal Events, Mineralogy and Geochemistry of Tourmaline Breccia in the Giant Río Blanco – Los Bronces Porphyry Copper Deposit, Central ChileHohf Riveros, Michael 26 April 2021 (has links)
The Río Blanco–Los Bronces (Chile) is one of the richest endowed porphyry copper-molybdenum districts worldwide, where about 20% of the known mineralization is hosted by tourmaline-cemented hydrothermal breccia.
This work seeks: (1) to find a relationship between tourmaline chemical and/or isotopic composition and the degree of mineralization in the breccia, (2) to constrain the source of the mineralizing fluid in the breccia, and (3) to determine of the composition and age of intrusive units in three new exploration projects and correlate them with the known intrusive rocks of the mine areas. Tourmaline from mineralized and barren breccias has similar boron isotopic compositions but differences in Mg/(Mg+Fe) ratios, Al-contents and Al-Fe correlation, which may have exploration value. Boron and sulfur isotopes results are consistent with a magmatic source of hydrothermal fluids. Results of whole rock geochemistry and U-Pb and 40Ar/39Ar geochronology of intrusive units, breccia and late-stage veins are combined with previous U-Pb, Ar/Ar and Re-Os ages to elucidate the magmatic and hydrothermal history of the district.:1 Introduction
1.1 Motivation of the study and statement of research questions
1.2 Scope of the study
2 Porphyry copper deposits (PCDs)
2.1 Introduction
2.1.1 Global copper inventory
2.1.2 Definition and classification of PCDs
2.2 Regional scale characteristics of PCDs
2.2.1 Tectonic setting
2.2.2 Space and time distribution
2.2.3 Porphyry stocks and their pluton and volcanic connections
2.2.4 Wall-rock Influence
2.3 Deposit-scale characteristics
2.3.1 Porphyry stocks and dikes
2.3.2 Hydrothermal breccia
2.3.3 Alteration-mineralization zoning
2.4 Processes of PCD formation
2.4.1 Arc magmatism
2.4.2 Magmatic volatiles
2.4.3 Genetic models
3 Regional setting of the study area
3.1 Tectono-magmatic setting
3.2 Metallogenic belts
4 Río Blanco – Los Bronces mining district
4.1 Mining history
4.2 District geology
4.2.1 Stratified rocks
4.2.2 Plutonic and hypabyssal intrusions
4.2.3 Structures
4.2.4 Alteration and mineralization
4.2.1 Geochronology database
5 Results
5.1 Plutonic units
5.1.1 Petrography
5.1.2 Whole rock (WR) geochemistry
5.1.3 Geochronology
5.2 Mineralization
5.2.1 Petrography
5.2.2 Tourmaline occurrence and composition
5.2.3 Sulfides and sulfates
6 Discussion
6.1 Time-space relationships of intrusion, brecciation and hydrothermal alteration
6.2 Stable isotope constraints on fluid source and evolution
6.2.1 Oxygen, hydrogen and sulfur isotopes
6.2.2 Boron isotopes
6.3 Tourmaline as a redox indicator and significance for exploration
7 Summary and conclusions
8 References
Digital supplement
Appendix (Methods)
9 Appendix Methods
9.1 Optical microscopy (OM)
9.2 Scanning electron microscope (SEM) and energy-dispersive X-ray spectroscopy (EDS)
9.3 Whole rock chemical analysis
9.4 Electron microprobe analyses (EMPA)
9.5 Boron isotopes
9.6 Sulfur isotopes
9.7 40Ar/39Ar dating
9.8 Zircon separation and characterization
9.9 U-Pb zircon LA-ICP-MS dating
9.10 U-Pb zircon CA-ID-TIMS dating
9.11 Single zircon evaporation as screening method
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| 136 |
Vznik a vývoj davelského vulkanického komplexu / Petrogenesis and evolution of the Davle Volcanic ComplexSantolík, Václav January 2021 (has links)
The Davle Volcanic Complex (DVC) situated in the Teplá-Barrandian unit (TBU) of the Bohemian Massif, is considered as a Neoproterozoic-Cambrian magmatic arc that developed on the northern active margin of Gondwana supercontinent during Cadomian accretionary orogeny. This study combines data obtained from fieldwork, petrography, rock-forming mineral microanalysis, major and trace element analysis, Sr-Nd-Pb isotopic systematics and U-Pb zircon geochronology in order to reveal the petrogenesis and evolution of the DVC. At least three-stage metamorphism including Cadomian seafloor alteration, Variscan regional metamorphism as well as contact metamorphism related to the emplacement of the Central Bohemian Plutonic Complex affected the DVC. The studied rocks follow calc-alkaline trend whereas tholeiitic trend previously reported is rather related to younger magmatic events. The northern part of the DVC is dominated by felsic subvolcanic (plagiogranite), volcanic (dacite- rhyolite) and pyroclastic (dacitic-rhyolitic tuffs and breccias) rocks with a few outcrops of basaltic andesite-andesite pillow lavas documenting the subaqueous activity of the DVC. These rocks are Na-rich, but K-poor, the plagiogranite contains albite most likely primary in origin, and exhibit highly radiogenic εNd values (~ +6 to +11),...
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Erläuterungen zur Karte 'Mineralische Rohstoffe Erzgebirge-Vogtland/Krushé hory 1:100 000, Karte 2: Metalle, Fluorit/Baryt - Verbreitung und Auswirkungen auf die UmweltHösel, Günter, Tischendorf, Gerhard, Wasternack, Jürgen 04 January 2022 (has links)
Erstmals seit dem 2. Weltkrieg wird mit der Karte eine vollständige Übersicht über die im genannten Raum bebauten oder noch vorhandenen o. g. mineralischen Rohstoffe gegeben. Auf der Karte im Maßstab 1:100.000 kommen Verbreitung, Intensität und Genese dieser Rohstoffe zur Darstellung. Die Karte liegt der Broschüre nicht bei, sondern kann beim Staatsbetrieb Geobasisinformation und Vermessung Sachsen erworben werden.
Redaktionsschluss: 30.11.1996
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Improving drill-core hyperspectral mineral mapping using machine learningContreras Acosta, Isabel Cecilia 21 July 2022 (has links)
Considering the ever-growing global demand for raw materials and the complexity of the geological deposits that are still to be found, high-quality extensive mineralogical information is required. Mineral exploration remains a risk-prone process, with empirical approaches prevailing over data-driven strategy. Amongst the many ways to innovate, hyperspectral imaging sensors for drill-core mineral mapping are one of the disruptive technologies. This potential could be multiplied by implementing machine learning. This dissertation introduces a workflow that allows the use of supervised learning to map minerals by means of ancillary data commonly acquired during exploration campaigns (i.e., mineralogy, geochemistry and core photography). The fusion of hyperspectral with such ancillary data allows not only to upscale to complete boreholes information acquired locally, but also to enhance the spatial resolution of the mineral maps. Thus, the proposed approaches provide digitally archived objective maps that serve as vectors for exploration and support geologists in their decision making.:List of Figures xviii
List of Tables xix
List of Acronyms xxi
1 Introduction 1
1.1 Mineral resources and the need for innovation . . . . . . . . . . . . . 2
1.2 Spectroscopy and hyperspectral imaging . . . . . . . . . . . . . . . . 5
1.2.1 Imaging spectroscopy ....................... 6
1.2.2 Spectroscopy of minerals ..................... 8
1.2.3 Mineral mapping.......................... 12
1.2.4 Mineral mapping in exploration ................. 15
1.2.5 Drill-core mineral mapping.................... 16
1.3 Machine learning .............................. 19
1.3.1 Supervised learning for drill-core hyperspectral data . . . . . 20
1.4 Motivation and approach ......................... 22
2 Hyperspectral mineral mapping using supervised learning and mineralogical data 25
Preface ....................................... 25
Abstract....................................... 26
2.1 Introduction ................................. 27
2.2 Data acquisition............................... 30
2.2.1 Hyperspectral data......................... 30
2.2.2 High-resolution mineralogica ldata . . . . . . . . . . . . . . . 31
2.3 Proposed system architecture ....................... 33
2.3.1 Re-sampling and co-registration ................. 33
2.3.2 Classification ............................ 35
2.4 Experimental results ............................ 36
2.4.1 Data description .......................... 36
2.4.2 Experimental setup......................... 37
2.4.3 Quantitative and qualitative assessment . . . . . . . . . . . . . 37
2.5 Discussion.................................. 40
2.6 Conclusion.................................. 42
3 Geochemical and hyperspectral data integration 45
Preface ....................................... 45
Abstract....................................... 46
3.1 Introduction ................................. 47
3.2 Basis for the integration of geochemical and hyperspectral data . . . 50
3.3 Proposed approach ............................. 51
3.3.1 Geochemical data labeling..................... 51
3.3.2 Superpixel segmentation ..................... 53
3.3.3 Classification ............................ 53
3.4 Experimental results ............................ 54
3.4.1 Data description .......................... 54
3.4.2 Data acquisition........................... 55
3.4.3 Experimental setup......................... 55
3.4.4 Assessment of the geochemical data labeling . . . . . . . . . . 58
3.4.5 Quantitative and Qualitative Assessment . . . . . . . . . . . . 58
3.5 Discussion.................................. 61
3.6 Conclusion.................................. 63
4 Improved spatial resolution for mineral mapping 65
Preface ....................................... 65
Abstract....................................... 66
4.1 Introduction ................................. 67
4.2 Methods: Resolution Enhancement for Mineral Mapping . . . . . . . 69
4.2.1 Hyperspectral Resolution Enhancement . . . . . . . . . . . . . 69
4.2.2 Mineral Mapping.......................... 71
4.2.3 Supervised Classification ..................... 71
4.3 Case Study.................................. 72
4.3.1 Data Acquisition .......................... 72
4.3.2 Resolution Enhancement Application . . . . . . . . . . . . . . 74
4.3.3 Evaluation of the Resolution Enhancement . . . . . . . . . . . 75
4.4 Results .................................... 76
4.4.1 Mineral Mapping.......................... 76
4.4.2 Supervised Classification ..................... 77
4.4.3 Validation .............................. 80
4.5 Discussion.................................. 82
4.6 Conclusions ................................. 84
5 Bibliography 92
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Postglazialer Anstieg des Meeresspiegels, Paläoklima und Hydrographie, aufgezeichnet in Sedimenten der Bermuda inshore waters / Postglacial rise of sea level, palaeoclimate and hydrography, recorded in sediments of the Bermuda inshore watersVollbrecht, Rüdiger Dr. 13 January 1997 (has links)
No description available.
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Drone-based Integration of Hyperspectral Imaging and Magnetics for Mineral ExplorationJackisch, Robert 15 August 2022 (has links)
The advent of unoccupied aerial systems (UAS) as disruptive technology has a lasting impact on remote sensing, geophysics and most geosciences. Small, lightweight, and low-cost UAS enable researchers and surveyors to acquire earth observation data in higher spatial and spectral resolution as compared to airborne and satellite data. UAS-based applications range from rapid topographic mapping using photogrammetric techniques to hyperspectral and geophysical measurements of surface and subsurface geology. UAS surveys contribute to identifying metal deposits, monitoring of mine sites and can reveal arising environmental issues associated with mining. Further, affordable UAS technology will boost exploration data availability and expertise in the global south.
This thesis investigates the application of UAS-based multi-sensor data for mineral exploration, in particular the integration of hyperspectral imagers, magnetometers and digital cameras (covering the visible red, green, blue light spectrum). UAS-based research is maturing, however the aforementioned methods are not unified effectively. RGB-based photogrammetry is used to investigate topography and surface texture. Image spectrometers measure mineral-specific surface signatures. Magnetometers detect geomagnetic field changes caused by magnetic minerals at surface and depth. The integration of such UAS sensor-based methods in this thesis augments exploration potential with non-invasive, high-resolution, safe, rapid and practical survey methods.
UAS-based surveying acquired, processed and integrated data from three distinct test sites. The sites are located in Finland (Fe-Ti-V at Otanmäki; apatite at Siilinjärvi) and Greenland (Ni-Cu-PGE at Qullissat, Disko Island) and were chosen as geologically diverse areas in subarctic to arctic environments. Restricted accessibility, unfavourable atmospheric conditions, dark rocks, debris and vegetation cover and low solar illumination were common features. While the topography in Finland was moderately flat, a steep landscape challenged the Greenland field work. These restraints meant that acquisitions varied from site to site and how data was integrated and interpreted is dependent on the commodity of interest.
Iron-based spectral absorption and magnetic mineral response were detected using hyperspectral and magnetic surveying in Otanmäki. Multi-sensor-based image feature detection and classification combined with magnetic forward modelling enabled seamless geologic mapping in Siilinjärvi. Detailed magnetic inversion and multispectral photogrammetry led to the construction of a comprehensive 3D model of magmatic exploration targets in Greenland. Ground truth at different intensity was employed to verify UAS-based data interpretations during all case studies.
Laboratory analysis was applied when deemed necessary to acquire geologic-mineralogic validation (e.g., X-ray diffraction and optical microscopy for mineral identification to establish lithologic domains, magnetic susceptibility measurements for subsurface modelling), for example for trace amounts of magnetite in carbonatite (Siilinjärvi) and native iron occurrence in basalt (Qullissat). Technical achievements were the integration of a multicopter-based prototype fluxgate-magnetometer data from different survey altitudes with ground truth, and a feasibility study with a high-speed multispectral image system for fixed-wing UAS.
The employed case studies transfer the experiences made towards general recommendations for UAS application-based multi-sensor integration. This thesis highlights the feasibility of UAS-based surveying at target scale (1–50 km2) and solidifies versatile survey approaches for multi-sensor integration. / Ziel dieser Arbeit war es, das Potenzial einer Drohnen-basierten Mineralexploration mit Multisensor-Datenintegration unter Verwendung optisch-spektroskopischer und magnetischer Methoden zu untersuchen, um u. a. übertragbare Arbeitsabläufe zu erstellen.
Die untersuchte Literatur legt nahe, dass Drohnen-basierte Bildspektroskopie und magnetische Sensoren ein ausgereiftes technologisches Niveau erreichen und erhebliches Potenzial für die Anwendungsentwicklung bieten, aber es noch keine ausreichende Synergie von hyperspektralen und magnetischen Methoden gibt.
Diese Arbeit umfasste drei Fallstudien, bei denen die Drohnengestützte Vermessung von geologischen Zielen in subarktischen bis arktischen Regionen angewendet wurde.
Eine Kombination von Drohnen-Technologie mit RGB, Multi- und Hyperspektralkameras und Magnetometern ist vorteilhaft und schuf die Grundlage für eine integrierte Modellierung in den Fallstudien.
Die Untersuchungen wurden in einem Gelände mit flacher und zerklüfteter Topografie, verdeckten Zielen und unter oft schlechten Lichtverhältnissen durchgeführt. Unter diesen Bedingungen war es das Ziel, die Anwendbarkeit von Drohnen-basierten Multisensordaten in verschiedenen Explorationsumgebungen zu bewerten.
Hochauflösende Oberflächenbilder und Untergrundinformationen aus der Magnetik wurden fusioniert und gemeinsam interpretiert, dabei war eine selektive Gesteinsprobennahme und Analyse ein wesentlicher Bestandteil dieser Arbeit und für die Validierung notwendig.
Für eine Eisenerzlagerstätte wurde eine einfache Ressourcenschätzung durchgeführt, indem Magnetik, bildspektroskopisch-basierte Indizes und 2D-Strukturinterpretation integriert wurden. Fotogrammetrische 3D-Modellierung, magnetisches forward-modelling und hyperspektrale Klassifizierungen wurden für eine Karbonatit-Intrusion angewendet, um einen kompletten Explorationsabschnitt zu erfassen. Eine Vektorinversion von magnetischen Daten von Disko Island, Grönland, wurden genutzt, um großräumige 3D-Modelle von undifferenzierten Erdrutschblöcken zu erstellen, sowie diese zu identifizieren und zu vermessen.
Die integrierte spektrale und magnetische Kartierung in komplexen Gebieten verbesserte die Erkennungsrate und räumliche Auflösung von Erkundungszielen und reduzierte Zeit, Aufwand und benötigtes Probenmaterial für eine komplexe Interpretation.
Der Prototyp einer Multispektralkamera, gebaut für eine Starrflügler-Drohne für die schnelle Vermessung, wurde entwickelt, erfolgreich getestet und zum Teil ausgewertet.
Die vorgelegte Arbeit zeigt die Vorteile und Potenziale von Multisensor-Drohnen als praktisches, leichtes, sicheres, schnelles und komfortabel einsetzbares geowissenschaftliches Werkzeug, um digitale Modelle für präzise Rohstofferkundung und geologische Kartierung zu erstellen.
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