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Chemical nature and plant availability of phosphorus present in soils under long-term fertilised irrigated pastures in Canterbury, New ZealandCondron, Leo M. January 1986 (has links)
Soil P fractionation was used to examine changes in soil inorganic and organic P under grazed irrigated pasture in a long-term field trial at Winchmore in Mid-Canterbury. The soil P fractionation scheme used involved sequential extractions of soil with O.5M NaHCO₃ @ pH 8.5 (NaHCO₃ P), 0.1M NaOH (NaOH I P), 1M HCl (HCl P) and 0.1M NaOH (NaOH II P). The Winchmore trial comprised 5 treatments: control (no P since 1952), 376R (376 kg superphosphate ha⁻¹ yr⁻¹ 1952-1957, none since), 564R (564 kg superphosphate ha⁻¹ yr⁻¹ 1952-1957, none since) 188PA (188 kg superphosphate ha⁻¹ yr⁻¹ since 1952) and 376PA (376 kg superphosphate ha⁻¹ yr⁻¹ since 1952: Topsoil (0-7.5cm) samples taken from the different treatments in 1958, 1961, 1965, 1968, 1971, 1974 and 1977 were used in this study. Changes in soil P with time showed that significant increases in soil inorganic P occurred in the annually fertilised treatments (l88PA, 376PA). As expected, the overall increase in total soil inorganic P between 1958 and 1977 was greater in the 376PA treatment (159 µg P g⁻¹) than that in the 188PA treatment (37 µg P g⁻¹). However, the chemical forms of inorganic P which accumulated in the annually fertilised treatments changed with time. Between 1958 and 1971 most of the increases in soil inorganic P in these treatments occurred in the NaHCO₃ and NaOH I P fractions. On the other hand, increases in soil inorganic P in the annually fertilised treatments between 1971 and 1977 were found mainly in the HCl and NaOH II P fractions. These changes in soil P forms were attributed to the combined effects of lime addition in 1972 and increased amounts of sparingly soluble apatite P and iron-aluminium P in the single superphosphate applied during the 1970's. In the residual fertiliser treatments (376R, 564R) significant decreases in all of the soil inorganic P fractions (i.e. NaHCO₃ P, NaOH I P, HCl P, NaOH II p) occurred between 1958 and 1977 following the cessation of P fertiliser inputs in 1957. This was attributed to continued plant uptake of P accumulated in the soil from earlier P fertiliser additions. However, levels of inorganic P in the different soil P fractions in the residual fertiliser treatments did not decline to those in the control which indicated that some of the inorganic P accumulated in the soil from P fertiliser applied between 1952 and 1957 was present in very stable forms. In all treatments, significant increases in soil organic P occurred between 1958 and 1971. The overall increases in total soil organic P were greater in the annually fertilised treatments (70-86 µg P g⁻¹) than those in the residual fertiliser (55-64 µg P g⁻¹) and control (34 µg P g⁻¹) treatments which reflected the respective levels of pasture production in the different treatments. These increases in soil organic P were attributed to the biological conversion of native and fertiliser inorganic P to organic P in the soil via plant, animal and microbial residues. The results also showed that annual rates of soil organic P accumulation between 1958 and 1971 decreased with time which indicated that steady-state conditions with regard to net 'organic P accumulation were being reached. In the residual fertiliser treatments, soil organic P continued to increase between 1958 and 1971 while levels of soil inorganic P and pasture production declined. This indicated that organic P which accumulated in soil from P fertiliser additions was more stable and less available to plants than inorganic forms of soil P. Between 1971 and 1974 small (10-38 µg P g⁻¹) but significant decreases in total soil organic P occurred in all treatments. This was attributed to increased mineralisation of soil organic P as a result of lime (4 t ha⁻¹) applied to the trial in 1972 and also to the observed cessation of further net soil organic P accumulation after 1971. Liming also appeared to affect the chemical nature of soil organic P as shown by the large decreases in NaOH I organic P(78-88 µg P g⁻¹) and concomitant smaller increases in NaOH II organic P (53-65 µg P g⁻¹) which occurred in all treatments between 1971 and 1974. The chemical nature of soil organic P in the Winchmore long-term trial was also investigated using 31p nuclear magnetic resonance (NMR) spectroscopy and gel filtration chromatography. This involved quantitative extraction of organic P from the soil by sequential extraction with 0.1M NaOH, 0.2M aqueous acetylacetone (pH 8.3) and 0.5M NaOH following which the extracts were concentrated by ultrafiltration. Soils (0-7.5cm) taken from the control and 376PA annually fertilised treatments in 1958, 1971 and 1983 were used in this study. 31p NMR analysis showed that most (88-94%) of the organic P in the Winchmore soils was present as orthophosphate monoester P while the remainder was found as orthophosphate diester and pyrophosphate P. Orthophosphate monoester P also made up almost all of the soil organic P which accumulated in the 376PA treatment between 1958 and 1971. This indicated that soil organic P in the 376PA and control treatments was very stable. The gel filtration studies using Sephadex G-100 showed that most (61-83%) of the soil organic P in the control and 376PA treatments was present in the low molecular weight forms (<100,000 MW), although the proportion of soil organic P in high molecular weight forms (>100,000 MW) increased from 17-19% in 1958 to 38-39% in 1983. The latter was attributed to the microbial humification of organic P and indicated a shift toward more complex and possibly more stable forms of organic P in the soil with time. Assuming that the difference in soil organic P between the control and 376PA soils sampled in 1971 and 1983 represented the organic P derived from P fertiliser additions, results showed that this soil organic P was evenly distributed between the high and low molecular weight fractions. An exhaustive pot trial was used to examine the relative availability to plants of different forms of soil inorganic and organic P in long-term fertilised pasture soils. This involved growing 3 successive crops of perennial ryegrass (Lolium perenne) in 3 Lismore silt loam (Udic Ustochrept) soils which had received different amounts of P fertiliser for many years. Two of the soils were taken from the annually fertilised treatments in the Winchmore long term trial (188PA, 376PA) and the third (Fairton) was taken from a pasture which had been irrigated with meatworks effluent for over 80 years (65 kg P ha⁻¹ yr⁻¹). Each soil was subjected to 3 treatments, namely control (no nutrients added), N100 and N200. The latter treatments involved adding complete nutrient solutions with different quantities of N at rates of 100kg N ha⁻¹ (N100) and 200kg N ha⁻¹ (N200) on an area basis. The soil P fractionation scheme used was the same as that used in the Winchmore long-term trial study (i.e. NaHCO₃ P, NaOH I P, HCl P, NaOH II p). Results obtained showed that the availability to plants of different extracted inorganic P fractions, as measured by decreases in P fractions before and after 3 successive crops, followed the order: NaHCO₃ P > NaOH I P > HCl P = NaOH II P. Overall decreases in the NaHCO₃ and NaOH I inorganic P fractions were 34% and 16% respectively, while corresponding decreases in the HCl and NaOH II inorganic P fractions were small «10%) and not significant. However, a significant decrease in HCl P (16%) was observed in one soil (Fairton-N200 treatment) which was attributed to the significant decrease in soil pH (from 6.2 to 5.1) which occurred after successive cropping. Successive cropping had little or no effect on the levels of P in the different soil organic P fractions. This indicated that net soil organic P mineralisation did not contribute significantly to plant P uptake over the short-term. A short-term field experiment was also conducted to examine the effects of different soil management practices on the availability of different forms of P to plants in the long-term fertilised pasture soils. The trial was sited on selected plots of the existing annually fertilised treatments in the Winchmore long-term trial (188PA, 376PA) and comprised 5 treatments: control, 2 rates of lime (2 and 4 t ha⁻¹ ) , urea fertiliser (400kg N ha⁻¹ ) and mechanical cultivation. The above ground herbage in the uncultivated treatments was harvested on 11 occasions over a 2 year period and at each harvest topsoil (0-7.5 cm) samples were taken from all of the treatments for P analysis. The soil P fractionation scheme used in this particular trial involved sequential extractions with 0.5M NaHCO₃ @ pH 8.5 (NaHCO₃ P), 0.1M NaOH (NaOH P), ultrasonification with 0.1M NaOH (sonicate-NaOH p) and 1M HCl (HCl P). In addition, amounts of microbial P in the soils were determined. The results showed that liming resulted in small (10-21 µg P g⁻¹) though significant decreases in the NaOH soil organic P fraction in the 188PA and 376PA plots. Levels of soil microbial P were also found to be greater in the limed treatments compared with those in the controls. These results indicated that liming increased the microbial mineralisation of soil organic P in the Winchmore soils. However, pasture dry matter yields and P uptake were not significantly affected. Although urea significantly increased dry matter yields and P uptake, it did not appear to significantly affect amounts of P in the different soil P fractions. Mechanical cultivation and the subsequent fallow period (18 months) resulted in significant increases in amounts of P in the NaHCO₃ and NaOH inorganic P fractions. This was attributed to P released from the microbial decomposition of plant residues, although the absence of plants significantly reduced levels of microbial P in the cultivated soils. Practical implications of the results obtained in the present study were presented and discussed.
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Réservoirs fluides et transferts en contexte d'exhumation orogénique : implications sur la position structurale des minéralisations Cu-Pb-Zn-Fe-Ag dans la région Lavrion-Eubée (Grèce) / Stuctural position and geochemistry of fluids associated with Cu-Pb-Zn-Fe-Ag deposits in the Lavrion-Evia area (Greece)Scheffer, Christophe 07 December 2016 (has links)
Cette thèse est centrée sur la ceinture orogénique Attico-Cycladique formée durant l'orogénèse Alpine. Par une approche multi-méthodes et multi-échelles combinant géologie structurale, pétrographie, thermobarométrie des assemblages minéraux, géochimie élémentaire et isotopique, et données PVTX des inclusions fluides associées, ce travail vise à caractériser et comprendre les relations entre circulations fluides, interactions fluides/roches, déformation, et mobilisation-transport-dépôt des métaux. Les marbres et schistes de la péninsule du Lavrion et de l'île d'Eubée témoignent d'une évolution orogénique complexe marquée par une phase d'enfouissement à l'Eocène suivie par deux phases d'exhumation successives syn-et post-orogéniques. Les minéralisations de type Cu-Pb-Zn-Fe-Ag de la région du Lavrion sont synchrones de l’activation du détachement post-orogénique et de la mise en place de plutons de granodiorite. Leurs positions structurales témoignent d’un piégeage depuis un régime de déformation ductile jusqu'à fragile. Les minéralisations mises en place durant le régime de déformation ductile à ductile-fragile (skarn et remplacement de carbonate) sont associées à la décarbonatation des niveaux de marbres et à la circulation des fluides magmatiques. L'exhumation progressive de la racine orogénique se traduit par la transition des roches depuis une déformation ductile vers un régime fragile associé à l’ouverture du système aux fluides de surface et notamment aux fluides météoriques. Cette circulation est responsable d’une remobilisation des métaux des minéralisations primaires permettant alors une seconde phase de précipitation dans un régime cassant (veines épithermales) / This thesis is focused on the Attico-Cycladic orogenic wedge formed during the Alpine orogeny. From a multi-method and multi-scale approach using structural geology, petrography, mineral thermobarometry, element and isotope geochemistry, and PVTX data of associated fluid inclusions, this study deciphers the relationships between fluid circulation, fluid-rock interactions and mobilisation-transport-deposits of metals. Marbles and schists from the Evia Island and the Lavrion peninsula testify to a complex orogenic history marked by an Eocene burial phase followed by syn- and post-orogenic exhumation. Cu-Pb-Zn-Fe-Ag mineralisations from the Lavrion area are synchronous with the formation of the low-angle post-orogenic detachment and the emplacement of granodioritic magmas. The structural position of the deposits attests of an emplacement during ductile to brittle deformation conditions. Deposits associated with ductile to ductile-brittle deformation (skarn, carbonate replacement) are related to a marble decarbonation and magmatic fluid circulation. The progressive exhumation of the orogenic wedge allows the transition toward brittle conditions and opens the system to surficial meteoritic fluids. This meteoritic fluid circulation is responsible to remobilisation of metals from primary deposits allowing thus a second phase of deposition in a pure brittle deformation (epithermal veins)
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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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The Per Geijer iron ore deposits: Characterization based on mineralogical, geochemical and process mineralogical methodsKrolop, Patrick 04 April 2022 (has links)
The Per Geijer iron oxide-apatite deposits are important potential future resources for Luossavaara-Kiirunavaara Aktiebolag (LKAB), which has been continuously mining magnetite/hematite ores in northern Sweden for almost 130 years. The Per Geijer deposits reveal a high phosphorus content and vary from magnetite-dominated to hematite-dominated ores, respectively. The high phosphorus concentration of these ores results from highly elevated content of apatite as gangue mineral. Reliable, robust, and qualitative characterization of the mineralization is required as these ores inherit complex mineralogical and textural features. The precise mineralogical information obtained by optical microscopy, SEM-MLA and Raman improves the characterization of ore types and will benefit future processing strategies for this complex mineralization. The different approaches demonstrate advantages and disadvantages in classification, imaging, discrimination of iron oxides, and time consumption of measurement and processing. A comprehensive mineral-chemical dataset of magnetite, hematite and apatite obtained by electron microprobe analysis (EPMA) and LA-ICP-MS from representative drill core samples is presented. Magnetite, four different types of hematite and five types of apatite constitute the massive orebodies: Primary and pristine magnetite with moderate to high concentrations of Ti (∼61–2180 ppm), Ni (∼11–480 ppm), Co (∼5–300 ppm) and V (∼553–1831 ppm) indicate a magmatic origin for magnetite. The presence of fluorapatite and associated monazite inclusions and disseminated pyrite enclosed by magnetite with high Co:Ni ratios (> 10) in massive magnetite ores are consistent with a high temperature (∼ 800°C) genesis for the deposit. The different and abundant types of hematite, especially hematite type I, state subsequent hydrothermal events.
Chromium, Ni, Co and V in both magnetite and hematite have low concentrations in terms of current product regulations and thus no effect on final products in the future. In terms of a possible future hematite product, titanium seems to be the most critical trace element due to very high concentrations in hematite types I and IV, of which type I is most abundant in zones dominated by hematite. Further interest on other products is generated due to the high variability of hematite and apatite in some of these ores.
Information obtained from comminution test works in the laboratory scale can be utilized to characterize ore types and to predict the behavior of ore during comminution circuit in the industrial scale. Comminution tests with a laboratory rod and ball mill of 13 pre-defined ore types from the Per Geijer iron-oxide apatite deposits were conducted in this study. The highest P80 values were obtained by grinding in the rod mill for 10 minutes only (step A). Grinding steps B (25 min ball mill) and C (35 min ball mill) reveal very narrow P80 values. Ore types dominated by hematite have significantly higher P80 values after the primary grinding step (A), which indicates different hardness of the ore types. P80 values are generally lowest after the secondary grinding step C ranging between 26 µm (ore type M1a) and 80 µm (ore type H2a). Generally, Fe content increases in the finer particle size classes while CaO and P contents decrease. The influence of silica or phosphorus seems to be dependent on the dominant iron oxide. Magnetite-dominated ore types are more likely to be affected in their comminution behavior by the presence of the silicates. Contrary, hematite-dominant ore types are rather influenced by the presence of apatite. The difference in the degree of liberation of magnetite and hematite between ore types depends rather on size fractions than the amount of gangue in the ore. Davis tube data indicates that magnetite can be separated from gangue quite efficiently in the magnetite-dominated ore types. Contrary to magnetite ore, hematite-dominated ore types cannot be processed by DT. It is favored to use strong magnetic separation in order to achieve a desirable hematite concentrate. The magnetic material recovered by DT is most efficiently separated at an intensity current of 0.2 A, whereas above 0.5 A the separation process is neglectable. Based on comminution and magnetic separation tests a consolidation to eight ore types is favored which supports possible future mining of the Per Geijer deposits.:Contents
ABSTRACT ……………………………………………………………………… I
CONTENTS ……………………………………………………………………… II
LIST OF FIGURES AND TABLES ……………………………………………… IV
LIST OF ABBREVIATIONS ……………………………………………… V
1 INTRODUCTION ……………………………………………………… 1
1.1 Background and motivation of study ……………………………… 2
1.2 Previous and current work on the Per Geijer deposits ……………… 3
1.3 The need for mineral processing and in-situ ore description ……………… 4
1.4 General and generic aspects on iron oxide apatite deposits ……………… 5
Chapter A
2 REGIONAL GEOLOGY ………………………………………………. 7
2.1 Local geology of the Kiruna area ……………………………………… 7
2.2 Geology of the Per Geijer deposits ……………………………………… 9
3 METHODOLOGY ……………………………………………………… 12
3.1 Core sampling and preparation ……………………………………… 12
3.2 SEM – MLA in-situ ore ……………………………………………… 14
3.3 Electron Probe Microanalyses (EPMA) ……………………………… 15
3.3.1 Iron oxide measurements ……………………………………… 15
3.3.2 Apatite measurements ……………………………………… 15
3.4 In-situ LA-ICP-MS ……………………………………………………… 16
3.5 Whole-rock geochemistry ……………………………………………… 18
3.5.1 Exploration drill core assays ……………………………… 18
3.5.2 Chemical assays of rock chips ……………………………… 18
4 RESULTS ……………………………………………………………… 19
4.1 Pre-definition of ore types ………………………………...……………. 19
4.2 Mineralogy of in situ ore ……………………………………………… 21
4.2.1 Ore Type M1a ……………………………………………… 21
4.2.2 Ore Type M1b ……………………………………………… 22
4.2.3 Ore Type M2a ……………………………………………… 23
4.2.4 Ore Type M2b ……………………………………………… 25
4.2.5 Ore Type HM1b ……………………………………………… 26
4.2.6 Ore Type HM2a ……………………………………………… 27
4.2.7 Ore Type HM2b ……………………………………………… 28
4.2.8 Ore Type H1a ……………………………………………… 29
4.2.9 Ore Type H1b ……………………………………………… 30
4.2.10 Ore Type H2a ……………………………………………… 31
4.2.11 Ore Type H2b ……………………………………………… 32
4.2.12 Comparison of ore types ……………………………………… 33
4.3 Geochemistry of in situ ore types ……………………………… 36
4.3.1 Whole-rock chemical assays of drill cores ……………………… 36
4.3.2 Whole-rock geochemistry of rock chips ……………………… 39
4.4 Mineral chemistry of iron oxides ……………………………………… 42
4.4.1 Iron oxides and associated minerals ……………………………… 42
4.4.2 Mineral chemistry of magnetite from Per Geijer ……………… 43
4.4.3 Mineral chemistry of hematite from Per Geijer ……………… 47
4.5 Mineral chemistry of apatite ……………………………………… 51
4.5.1 Apatite and associated minerals ……………………………… 51
4.5.2 Mineral chemistry of apatite from Per Geijer ……………… 53
Chapter B
5 COMMINUTION TESTS ……………………………………………… 58
5.1 Methodology of comminution tests ……………………………………… 59
5.1.1 Sampling for comminution tests ……………………………… 59
5.1.2 Comminution circuit ……………………………………………… 61
5.1.3 Energy consumption calculation ……………………………… 62
5.1.4 SEM – MLA ……………………………………………………… 64
6 MAGNETIC SEPARATION TESTS ……………………………… 65
6.1 Methodology of magnetic separation by Davis magnetic tube ……… 66
6.2 Davis magnetic tube tests for characterization of the Per Geijer ore types 66
6.3 Separation analysis based on the Henry-Reinhard charts .……………... 67
7 RESULTS OF COMMINUTION OF ORE TYPES ……………………… 69
7.1 General characteristics of magnetite-dominated ore types ……………… 69
7.2 General characteristics of hematite-dominated ore types ……………… 72
7.3 General characteristics of magnetite/hematite-mixed ore types ……… 75
7.4 General characteristics of low-grade ore types ……………………… 77
7.5 Mineral liberation characteristics of magnetite-dominated ore types 79
7.6 Mineral liberation characteristics of hematite-dominated ore types 83
7.7 Mineral liberation characteristics of magnetite/hematite-mixed ore types 87
7.8 Mineral liberation characteristics of low-grade ore types ……………… 90
7.9 Total energy consumption of ore types from the Per Geijer deposits 94
8 RESULTS OF MAGNETIC SEPARATION OF ORE TYPES ……… 95
8.1 Magnetic separation of magnetite-dominated ore types ……………… 95
8.2 Magnetic separation of hematite-dominated ore types ……………… 96
8.3 Magnetic separation of magnetite/hematite-mixed ore types ……………… 97
8.4 Magnetic separation of low-grade ore types ……………………………… 98
8.5 Henry-Reinhard charts ……………………………………………… 99
9 DISCUSSION ……………………………………………………… 101
9.1 Mineralogy of the in-situ ore types from the Per Geijer deposits ……… 101
9.2 Geochemistry of the in-situ ore types from the Per Geijer deposits ……… 103
9.3 Mineral chemistry of iron oxides from the Per Geijer deposits ……… 105
9.4 Mineral chemistry of apatite from the Per Geijer deposits ……………… 114
9.5 Comminution of ore types from Per Geijer ……………………… 119
9.6 Magnetic separation of ore types from Per Geijer ……………………… 120
9.7 Issues with process mineralogy of in-situ and grinded ore types ……… 121
10 CONCLUSIONS ……………………………………………………… 128
11 IMPLICATIONS FOR FUTURE WORK ……………………………… 131
12 REFERENCES ……………………………………………………………… 134
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Das Lagerstättengebiet Zobes-Bergen im Vogtland und benachbarte Uranvorkommen im Bereich des Bergener GranitmassivsHiller, Axel, Schuppan, Werner 23 March 2017 (has links)
Der Band enthält einen regionalgeologischen Überblick zur Region und die Beschreibung der Lagerstätten Zobes und Bergen sowie weiterer Uranvorkommen des Vogtlandes nach ihrem geologischem Aufbau und ihrer Erkundung. Am umfassendsten untersucht war die Gangmineralisation in der Uranlagerstätte Zobes. In ihr trat außerdem eine schichtgebundene Scheelit-Sulfid-Vererzung auf.
Nach Abschluss von Uranbergbau und -erkundung in Sachsen und Thüringen bleiben die geowissenschaftlichen Erkenntnisse und Erfahrungen von grundsätzlichem Interesse. Sie können als Grundlage für künftige regionalgeologische Forschungen und rohstofforientierte Untersuchungen dienen.
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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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Auswirkungen von Ökosystemmanipulationen auf Vorratsänderung und Freisetzung von C- und N- Verbindungen / Effects of ecosystem manipulations on stock change and flux of N- and C-compounds in soilHorváth, Balázs 28 July 2006 (has links)
No description available.
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Economics of nitrogen fertilization: Site-specific application, risk implications, and greenhouse gas emissionsKaratay, Yusuf Nadi 18 February 2020 (has links)
In Anbetracht des Kompromisses zwischen der Erzielung des höchsten Gewinns und der geringsten Umweltbelastung ist ein tiefes Verständnis der ökonomischen Folgen der Stickstoff (N) Düngung erforderlich. Die vorliegende Doktorarbeit liefert umfassende Einblicke in (i) die Auswirkungen des standortspezifischen N-Managements (SSNM) auf die Rentabilität und Risikominderung, (ii) die Auswirkungen von Unsicherheiten und Risikoeinflüssen auf optimale N-Düngergaben und (iii) das Potenzial und die Kosten der Vermeidung von Treibhausgas (THG) Emissionen durch N-Düngereduktion. Ein Modellierungsansatz wurde entwickelt, um die Wirkung von Ertrag und Proteingehalt, Wirtschafts- und Risikoauswirkungen sowie THG-Emissionen auf die N-Düngung zu simulieren. Die Ergebnisse der Arbeit zeigen, dass SSNM die Wirtschaftlichkeit verbessert, indem es eine höhere Weizenqualität und damit Preisprämien erzielt. SSNM reduziert das Risiko, die Backqualität nicht zu erreichen, und es gibt keine wesentlichen Nachteile beim Verlustrisikomanagement im Vergleich zum einheitlichen Management. Preisprämien für eine höhere Weizenqualität bieten Anreize für höhere N-Düngergaben. Prämien verflachen die Gewinnfunktion weiter, was unzureichende Argumente für eine Absenkung des N-Inputs aus der Wirtschaftlichkeitssicht liefert, selbst bei einer hohen Risikoaversion der Landwirte. Eine moderate Reduzierung der mineralischen N-Düngung kann die THG-Emissionen bei moderaten Opportunitätskosten mindern. Die THG-Vermeidung durch N-Düngereduktion in einer bestimmten Region kann unter Berücksichtigung kultur- und ertragszonenspezifischer Ertragswirkungen optimiert werden. Insgesamt liefert diese Arbeit wichtige Erkenntnisse über die Chancen und Nachteile der Anpassung der N-Düngergaben. Darüber hinaus leistet sie einen direkten Beitrag zur Identifizierung von kosten- und risikoeffizienten N-Managementoptionen und bildet die Grundlage für effektive politische Ansätze zur THG-Vermeidung durch selektive N-Düngereduktion. / Considering the tradeoff between achieving the highest profit and causing the lowest environmental impact, there is a need for a profound understanding of the economic consequences of nitrogen (N) fertilizer application. The present doctoral research provides comprehensive insights into (i) effects of site-specific N management (SSNM) on profitability and risk mitigation; (ii) impacts of uncertainties and risk implications on optimal N fertilizer rates; and (iii) potential and costs of mitigating greenhouse gas (GHG) emissions by N fertilizer reduction. A modelling approach was developed to simulate the response of yield, protein, economic and risk implications, and GHG emissions to N fertilizer application. Findings of the thesis show that SSNM improves profitability by achieving higher grain quality, thus, price premiums. SSNM reduces the risk of not reaching the baking grain quality and poses no considerable disadvantage on downside risk management compared to uniform management. Price premiums for higher wheat quality provide incentives for higher N input rates. Premiums further flatten the profit function, giving insufficient arguments for lowering N input from a farm profitability perspective, even in presence of high risk aversion of farmers. Moderate reduction of mineral N fertilizer can mitigate GHG emissions at moderate opportunity costs. GHG mitigation by N fertilizer reduction in a given region can be optimized considering crop and yield-zone-specific yield responses. Overall, this thesis provides important insights on chances and drawbacks of adjusting N fertilizer rates. Moreover, it makes a direct contribution in identifying cost- and risk-efficient N management options and provides a basis for effective policy approaches to reduce GHG emissions by selective N fertilizer reduction.
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