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Als Voraussetzung für die experimentellen Arbeiten wurde am Mineralogischen Institut in Frankfurt eine Hochdruckpresse mit einer Multi-Anvil-Apparatur vom Walker-Typ aufgebaut und kalibriert. Diese Arbeiten nahmen einen beträchtlichen Teil der Promotionszeit ein. In einer Reihe von Hochdruck-Experimenten wurde dann die maximale Löslichkeit von Aluminium und den Seltenerd-Elementen Lanthan, Gadolinium und Lutetium in den Phasen des CaSiO3-Systems im Druckbereich zwischen 2.0 und 13.0 GPa untersucht. Unsere Experimente ergaben eine Zunahme der maximalen Löslichkeit mit steigendem Druck, von Wollastonit über Ca-Walstromit, Larnit + Si-Titanit bis Ca-Perowskit. Ca-Perowskit zeigt extrem hohe SEE-Konzentrationen mit einem Maximum bei den mittleren SEE. In den anderen Phasen nimmt die Löslichkeit mit zunehmender Kompatibilität der SEE zu. Innerhalb der Stabilitätsfelder zeigte sich keine signifikante Druck- oder Temperatur-Abhängigkeit der maximalen Löslichkeit. Anhand der Mikrosonden-Analysen konnte gezeigt werden, dass der Einbau von Al und SEE in Ca-Walstromit nicht über eine gekoppelte Substitution erfolgt, sondern wahrscheinlich über eine Defektstruktur. Dies deckt sich mit unseren TEM-Untersuchungen an diesen synthetischen Produkten, die eine hohe Dichte an planaren Baufehlern mit leicht erhöhten SEE-Konzentrationen ergaben. In allen Ca-Silikat-Phasen lag die maximale Löslichkeit der Seltenen Erden höher als die Konzentration in natürlichen Proben. Damit steht fest, dass die in Einschlüssen gemessenen SEE-Gehalte „primär“ sind und sich nicht durch etwaige Entmischungen im Zuge einer Anpassung der Kristallstruktur an die veränderten P,T-Bedingungen verändert haben. Entmischungen in Form einer SEE-reichen Phase würden eine an LSEE extrem angereicherte Quelle voraussetzen. Ein Vergleich unserer Subsolidus-Experimente mit CaSiO3-Einschlüssen in Diamanten aus Guinea zeigt, dass einige mit bis zu 0.13 Gew.% Al2O3 an Aluminium gesättigt sind. Diese Tatsache ist besonders interessant bei der Interpretation Alhaltiger Einschlussphasen. Neben absoluten Spurenelement-Konzentrationen sind Verteilungskoeffizienten äußerst wertvolle Hilfsmittel bei der Bewertung natürlicher Proben. Die in der Literatur bestehenden Datensätze wurden mit unseren Kristall/Schmelz-Verteilungskoeffizienten bzw. Verteilungskoeffizienten zwischen Ca-Silikatphasen erweitert. Verteilungskoeffizienten der Seltenerd-Elemente zwischen Ca-Walstromit und Karbonat sind um eine Größenordnung höher als Ca-Walstromit/Schmelz-Verteilungskoeffizienten und zeigen eine größere Steigung zwischen den MSEE und den SSEE (Lu/Gd). Die Seltenen Erden verhalten sich sowohl in Larnit als auch in Si-Titanit inkompatibel, wobei DX/L La für Larnit etwa 0.1 und für CaSi2O5 etwa 0.002 ist, d.h. auch, dass die LSEE im Vergleich zu Si-Titanit bevorzugt in Larnit eingebaut werden. Al verhält sich in Si-Titanit Zusammenfassung 147 kompatibel (DX/LAl=4) und in Larnit leicht inkompatibel. Diese Ergebnisse decken sich mit Analysen an natürlichen Proben. Die SEE-Verteilungskoeffizienten zwischen Ca-Perowskit und Schmelze liegen mit Ausnahme von La über eins und zeigen in Übereinstimmung mit Literaturdaten ein Maximum bei Gd. Für Granat konnte gezeigt werden, dass der Einbau der SEE und Si in MgO-haltigen Kristallen in Abhängigkeit von Druck und Startzusammensetzung über eine Ca SEE2 Mg2 Si3O12- Komponente bzw. über eine Ca3 MgSi Si3O12-Komponente mit 6-fach koordiniertem Silizium erfolgt. In zahlreichen Experimenten kristallisierte eine neue Ca-SEE-Silikat-Phase mit Feldspat-Stöchiometrie. Dabei handelt es sich offenbar um ein Mischkristallsystem mit einem Endglied, in das vorwiegend die leichten SEE eingebaut werden und in einem zweiten mit vorwiegend schweren SEE. Ab einem Druck von etwa 10.0 GPa trennt ein Solvus die beiden Endglieder voneinander. In der Literatur ist bisher nur ein CaLa2Si2O8-Endglied beschrieben worden. In einigen Experimenten mit P und Li wurde zusätzlich untersucht, ob diese Elemente zur Rekonstruktion der Bildungsbedingungen von Diamanten verwendet werden können. Dabei zeigte sich, dass die max. Löslichkeit von Li in CaSiO3 näher an den natürlichen Probenzusammensetzungen liegt und damit möglicherweise Potential für die Rekonstruktion von Bildungsbedingungen hat. In einem weiteren Teil dieser Arbeit wurde die Kinetik retrograder Reaktionen im CaSiO3-System untersucht. Die für die In-Situ-Experimente mit Synchrotron-Strahlung notwendigen Versuchsaufbauten wurden von uns entwickelt und die entsprechenden Entwicklungsschritte und technischen Probleme ausführlich beschrieben. Anhand von Entlastungsexperimenten wurden die Disproportionierung von Ca-Perowskit zu Larnit + Si-Titanit und die Rekombination zu Ca-Walstromit bei unterschiedlichen Temperaturen und unter dem Einfluss von Wasser untersucht. Aufgrund der wenigen verwertbaren Daten, die uns vorliegen, konnten zwar keine Aktivierungsenergien berechnet werden, es sind aber aufgrund unser Beobachtungen folgende Feststellungen zu treffen: Die Reaktion von Ca-Perowskit zu Larnit + Si-Titanit erfolgt bei gleicher Temperatur offenbar um Größenordnungen schneller als die sich bei niedrigen Drucken anschließende Rekombination zu Ca-Walstromit. Dies deckt sich mit Beobachtungen an natürlichen Proben, bei denen Larnit und Si-Titanit teilweise unvollständig zu Ca-Walstromit reagierten. Dadurch erscheint es eher unwahrscheinlich, dass amorphes CaSiO3 in Diamanten ein direktes Umwandlungsprodukt von Ca-Perowskit ist. Aber auch für die in der Literatur beschriebene Amorphisierung von Ca-Walstromit-Einschlüssen (Stachel 2000) noch innerhalb des umgebenden Diamanten ließ sich durch unsere In-Situ-Entlastungsexperimente nicht stützen. Eine Amorphisierung von Ca-Walstromit beobachteten wir nur bei einer Untersuchung am TEM, wo die Phase sehr instabil war und selbst in einem Kryohalter rasch unter dem Einfluss der Elektronenstrahls amorphisierte. Die Beugungs-Spektren, die nach einer Druckentlastung im Ca-Walstromit-Stabilitätsfeld aufgenommen wurden, unterschieden sich trotz der CaSiO3-Chemie der neu gebildeten Phase deutlich von unseren Ca-Walstromit-Referenz-Spektren, so dass die Umwandlung möglicherweise über eine metastabile Zwischenstufe erfolgt. Vor dem Hintergrund von unterschiedlichen, in der Literatur beschriebenen Strukturtypen von Ca-Walstromit wäre eine systematische Untersuchung der Struktur innerhalb des gesamten Stabilitätsfeldes wichtig.

This PhD thesis has been carried out within an interdisciplinary cooperational project between the Deutsches Bergbau-Museum Bochum and the Goethe-Universität Frankfurt, which is dedicated to ancient Pb-Ag mining and metal production in the hinterland of the municipium Ulpiana in central Kosovo. Geochemical analysis (OM, XRD, EMP, MC-ICP-MS) of ores, metallurgical (by-) products and metal artefacts allowed to reconstruct the local chaîne opératoire and to decipher significant chronological differences between presumably Roman/late antique and medieval/early modern metallurgical processing. Pb isotope provenance studies documented the relevance of local metal production within the Roman Empire and confirmed the actual existence of a Metalla Dardanica district, which until now solely has been suspected on basis of epigraphy. The predominant abundance of the by-products matte (Cu, Pb, Fe and Zn sulphides) and speiss (ferrous speiss: Fe-As compounds; base metal speiss: ~(Cu,Ni,Fe,Ag )x(Sb,Sn,As )y ) at smelting sites with a preliminary Roman/late antique dating points to treatment of complex polymetallic ore. Pb isotope analysis demonstrated that the mining district of Shashkoc-Janjevo (partially) supplied six of the ten investigated metallurgical sites. In this mineralisation, parageneses with elevated Cu, As and Sb abundances comprise significant proportions of particularly tennantite-tetrahedrite minerals, chalcopyrite, arsenopyrite and were generated during the early and main stages of ore formation. Later precipitated ore in contrast is marked by a significantly less versatile mineralogy and consists almost exclusively of galena, sphalerite and pyrite/marcasite. Besides increased Cu, As and Sb contents, ore from the main formation stage also exhibits generally higher Ag abundances, which are mainly hosted by fahlore and locally abundant secondary Cu sulphides (chalcocite, digenite and covellite) and oxidised phases (e.g. malachite, azurite). The higher precious metal grades of this ore type, whose geochemical signature (i.e. higher proportions of Cu, As and Sb) is mirrored by the abundance of the metallurgical by-products matte and speiss (almost exclusively found at potentially Roman/late antique smelting sites; see above), presumably were a pivotal factor leading to its preferential exploitation in earlier times. Matte and base metal-rich speiss contain notable amounts of Ag, which are mainly present in Cu-(Fe) sulphides and particularly antimonides ((Cu,Ni)2Sb, Ag3Sb), respectively. While the speiss compounds due to their close association with Pb bullion presumably were cupelled automatically, the metallurgical treatment of matte could not have been proven unambiguously, but overall certainly is highly likely. The beneficiated ore (i.e. crushed and sorted, potentially also treated by more lavish techniques such as grinding, sieving or wet-mechanical methods) possibly was partially roasted and subsequently together with fluxes and charcoal submitted to the furnaces. The working temperatures approximately ranged between 1100 and 1400 °C. Slags from all presumably Roman/late antique dated and few of their potentially medieval/early modern analogues were produced from smelting of (partially roasted) ore with charcoal and added siliceous material, thus resulting in fayalite-dominant phase assemblages or rarely observed glassy parageneses. Even though several subtypes of fayalite slags have been established on basis of the abundance of Fe-rich oxide phases (i.e. spinel ss and wüstite), late clinopyroxene and the general solidification sequence of the slags, the process conditions (i.e. temperature, fO2, added fluxing agents) must have been widely similar; chemical variations could be explained by varying degrees of interaction of the slag melt with charcoal ash and furnace material. The other investigated metallurgical remains indicate employment of a calcareous flux, which led to formation of Ca-rich olivine-, olivine+clinopyroxene-, clinopyroxene- or melilite-type slags. These types as well as glassy slags were generated at more oxidising conditions outside the fayalite stability field (FMQ buffer equilibrium, cf. Lindsley, 1976) than their olivine-dominant analogues. Conclusions on the furnace construction could be drawn on basis of the typology of the slags, which mostly were tapped into a basin located outside the furnace, but partially (at two presumably medieval/early modern sites) also accumulated in a reservoir within the smelter. Lead artefacts excavated in Ulpiana could be isotopically related to ores from mineralisations in its vicinity and demonstrate that the resources were at least utilised for local metal production. However, also ship wreck cargo from Israel - including several lead ingots with the inscription 'MET DARD' (Raban, 1999) - and late antique lead-glazed pottery from Serbia and Romania (Walton & Tite, 2010) could be related to a possible Kosovarian/Serbian provenance of the raw material and thus indicate flourishing trade of metal from the Metalla Dardanica district within the Roman Empire. References: Lindsley, D. H. (1976). Experimental studies of oxide minerals. In D. Rumble, III (Hrsg.), Oxide minerals (61-88). Reviews in Mineralogy, Volume 3. Washington, DC: Mineralogical Society of America. Raban, A. (1999). The lead ingots from the wreck site (area K8). Journal of Roman Archaeology, Supplementary Series, 35, 179-188. Walton, M. S., & Tite, M. S. (2010). Production technology of Roman lead-glazed pottery and its continuance into late antiquity. Archaeometry, 52(5), 733-759.

The geodynamic processes and the chemical and thermal evolution of the mantle beneath the Kaapvaal craton (South Africa) was investigated with further regard to diamond formation. For this, 31 coarse-grained peridotites and 21 individual subcalcic garnets from heavy mineral concentrates (HMC) from the Finsch mine were studied for their major and trace element compositions, Lu-Hf and Sm-Nd isotope composition. Furthermore, processes in the Earth’s mantle that follow kimberlite sampling and propagation were studied in polymict peridotite breccia from Kimberley mines. Inter mineral equilibrium of the peridotites was tested by comparing the results from different, independent thermometers. These, well equilibrated peridotites stem from a restricted pressure of 5 to 6.5 GPa (depth ~160-200 km) and a temperature range of 1050-1250°C, following the 40 mW/m2 conductive geotherm. The majority of the samples display a well developed anti-correlation of oxygen fugacity with pressure, which is in contrast to the sheared and oxidised, younger kimberlite erupted peridotites from Kimberley. All analysed samples have homogeneous trace element mineral chemistry. Variations in trace elements among Finsch peridotites reflect their complex nature and the intricate development of the subcratonic mantle. The 3.6 Ga is the oldest crustal age recorded in the Kaapvaal craton, and is confirmed by the Lu-Hf model age of a highly radiogenic subcalcic garnet in this study. Therefore, this age probably represents the oldest depletion (partial melting event) of the subcratonic mantle beneath the Kaapvaal craton. Both, subcalcic garnets and Finsch peridotites yield Lu-Hf isochron ages of around 2.5 Ga, which probably represent the last depletion event of the Kaapvaal craton. Several older (than 2.5 Ga) depletions were also necessary to explain higher isochron initials of the both isochrones. The Cr# and HREE concentrations and ratios of the Finsch subcalcic garnets and peridotites indicate that partial melting of the Kaapvaal craton happened at different depths. One group of subcalcic garnets (group-1) experienced depletion at high pressure in the garnet stability field and another one (group-2) at low pressures in the spinel or plagioclase stability field. Major and trace elements indicate that up to 50%, of the melt was remover from the primitive (primer) mantle in at least two melting events. Thus, first continental crust was created early (> 2.5 Ga) from high degrees of partial melting of the lithospheric mantle. According to the Sm-Nd isotope signatures at least two metasomatic events took place significantly after 2.5 Ga. As monitored by group-1 subcalcic garnets, the first enrichment was produced by a fluid and occurred at around 1.3 Ga. The second metasomatic event was much later at 500-300 Ma ago and has changed both Nd and Hf isotopic compositions of group-2 subcalcic garnet as well as some Finsch peridotites. During partial melting any carbon species will be dissolved in the melt and removed from the residue. Therefore, any diamond growth before the last depletion (~2.5 Ga) would have been probably completely removed from the lithospheric mantle. Consequently, carbon was apparently reintroduced into the system, i.e. during Metasomatism, and triggered the growth of diamonds. The Sm-Nd isotope systematics of the subcalcic garnets of this study indicates that enrichment occurred at ~1.3 Ga or later, which implies non-Archean, late diamond growth in Finsch. Fertilisation of the subcontinental craton associated with the percolation of group-2 (~120 Ma) or even younger (~90 Ma) group-1 kimberlites and their precursors are not observed in Finsch peridotites, but are well presented in mantle xenoliths from Kimberley. Therefore, these younger events were studied on specific mantle xenoliths, polymict breccia from Kimberley. A polymict peridotite found at the Boshof road dump, Kimberley, represents a mechanical mixture of upper mantle clasts and minerals (opx, cpx, garnet and olivine) of different lithologies, cemented by fine-grained olivine and minute amounts of interstitial ilmenite, phlogopite and sulphide. According to Ni in garnet thermometry, single porphyroclastic garnets were sampled and mixed during ascent in a 100 km stratigraphic column, starting from ~250 km until ~120 km. During this ascent, melt has reacted with the porphyroclasts and at theirrims neoblastic minerals were formed, i.e. neoblastic opx around opx porphyroclast, neoblastic garnet around garnet porphyroclast, and neoblastic opx around cpx porphyroclast. Analyses of those neoblastic minerals indicate that volatile-rich, kimberlite-like melt was the agent that collected the mantle minerals and amalgamated this xenolith. Several complex processes were responsible for the formation of the polymict breccia. They comprise melt degassing at high pressures that probably created “explosive” Brecciation of the cratonic roots (~250 km), propagation of the melt that collected different porphyroclasts on a way and amalgamation at around 120 km. The whole process of “explosive” brecciation, turbulent transport and mixing of mantle porphyroclasts and melt, porphyroclast dissolution and neoblast precipitation happened very fast and was part of the kimberlite formation. Therefore, the here studied sample probably represents one frozen part (with variable mantle clasts) of the kimberlitic magma precursor, with kimberlite eruption at ~90 Ma years ago in Kimberley.

The Earth’s surface condition we find today is a result of long exposure to metabolism of life forms. Particularly, molecular oxygen in the atmosphere is a feature which developed over time. The first substantial and lasting rise of atmospheric oxygen level happened ≈ 2.5 Ga ago, but localities are reported where transiently elevated oxygen levels appeared before this time-point. To trace the timing and circumstances of the earliest availability of free oxygen in the atmosphere is important to understand the habitats of early microbial life forms on Earth. This thesis focuses to obtain information of oxygen levels and the related atmospheric cycling of metals in sediments of the 3.5 to 3.2 Ga Barberton Greenstone Belt. First, as iron was a ubiquitous constituent of Archean seawater, I investigated its isotopic composition in minerals of chemical sediments. Hereby, I tried to resolve the changes within the water basin on small scale sedimentary sequence cycles. Second, I focused on the minor constituents of Archean seawater. The Re-Os geochronologic system and the abundance patterns of the platinum-group elements were chosen to integrate information of oxygen promoted weathering of a large source area. To integrate information of a large time interval, the isotopes of uranium were investigated over a large stratigraphic section. The two key findings of this thesis are: • Quantitative oxidation of ferrous iron in surface layers of Paleoarchean seawater occurred during the onset and termination of hydrothermal FeIIaq delivery into shallow waters. • Paleoarchean sedimentary successions of the Barberton Greenstone Belt lack any evidence of transient basin-scale oxygenation. The Manzimnyama Iron Formation (IF, Fig Tree Group, Barberton Greenstone Belt, South Africa) has been deciphered to exist of cyclic stacks of lithostratigraphic units with varying amounts of iron oxide and carbonate minerals. In-situ femtosecond-Laser-Ablation ICP-MS iron isotope measurements showed that the majority of siderite (γ56Fe ≈ −0.5 ‰) precipitated directly from seawater of γ56Fe ≈ 0 ‰. Ferric iron from the surface layers is preserved in ≤ 1μ m hematite and in magnetite that has been grown within the consolidated sediment. During FeIIaq events, fine-grained hematite (γ56Fe ≈ 2.2 ‰) and magnetite (γ56Fe 0.5 to 0.8 ‰) indicate oxygen levels in surface waters of lower than 0.0002 μM. Upon onset and termination of iron oxide abundance, magnetite with γ56Fe ≈ 0 ‰ indicates that low concentrations of FeIIaq in surface waters were oxidized quantitatively. These observations demonstrate the existence of iron oxidation in Paleoarchean surface waters independent of FeIIaq concentration. This is the first investigation of Paleoarchean IF showing that lithostratigraphic cyclicity can be traced in iron isotopic composition of oxide minerals. ID-ICP-MS measurement of Re, Ir, Ru, Pt and Pd, trace element (SF-ICP-MS) and ID-MCICP- MS uranium isotope determination have been applied to carbonaceous shale of the Mapepe Fm. (Fig Tree Group) after inverse Aqua Regia leaching and bulk digestion. The sediments reveal a silicified fraction which exhibits a seawater REE signature and a mixture of detrital and meteoritic PGE. Neither enrichment of the redox-sensitive elements Re or Mo nor fractionated uranium isotopes have been found on a stratigraphic interval of several hundred meters. The non-silica fraction shows no depletion of Re which indicates that the detrital material had no contact to oxidizing fluids. ID-TIMS measurements of Re and Os after the CrO3-SO4 Carius Tube method of two sample intervals showed that the Re-Os isotopic systems of the non-silica fractions are identical to two komatiite occurrences. Weltevreden Fm. and Komati Fm. rocks were uplifted, eroded and transported to the deep part of the sedimentary basin without any change to the Re-Os system. Negative fractionated uranium isotopes (γ238U = −0.41 ± 0.01 ‰) associated with detrital Ba-Cr-U occurrences suggest the existence of distal redox-processes that involve uranium species. This study demonstrates that over the time of exposure and deposition of the Mapepe Fm. sedimentation, free oxygen was not available for weathering in the catchment area.