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Detailuntersuchung der magmatisch-hydrothermalen Goldvererzung des Conical Seamount (Papua-Neuguinea) mit Flachbohrungen : Abschlussbericht CONDRILL (03G0166) ; SO166 Condrill ; (01.06.2002 - 30.11.2004) (2004)

Herzig, Peter M.

Freiberg : Techn. Univ. Bergakad., Inst. für Mineralogie, Lehrstuhl für Lagerstättenlehre ...

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Keywords: Forschungsbericht

Type of Medium: Online Resource

Pages: Online-Ressource (267 S., 14,3 MB) , Ill., graph. Darst., Kt.

URL: https://edocs.tib.eu/files/e01fb06/510816096.pdf

URL: https://doi.org/10.2314/GBV:510816096

URL: https://edocs.tib.eu/files/e01fb06/510816096l.pdf

DOI: 10.2314/GBV:510816096

Language: German , English

Note: Literaturangaben , Unterschiede zwischen der gedruckten und der elektronischen Dokumentversion sind möglich , Auch als gedr. Ausg. vorhanden , Systemvoraussetzungen: Acrobat reader. , Text teilw. dt., teilw. engl.

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Drilling shallow water massive sulfides at the Palinuro Volcanic Complex, Aeolian Island Arc, Italy (2014)

Petersen, Sven ; Monecke, Thomas ; Westhues, Anne ; [et al.]

Society of Economic Geologists

In: Economic Geology, 109 (8). pp. 2129-2157.

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Publication Date: 2019-09-23

Description: A subseafloor replacement-style barite and sulfide occurrence was drilled in shallow waters at the Palinuro volcanic complex, the northernmost Aeolian arc volcano in the Tyrrhenian Sea, Italy. Using a lander-type drilling device, 11 successful drill holes yielded a total of 13.5 m of core from a sediment-filled depression located at a water depth of 630 to 650 m. The longest continuous drill core recovered consists of 4.84 m of massive to semimassive barite and sulfides with abundant late, native sulfur overprint. Seafloor observations suggest that the hydrothermal system associated with the formation of the subseafloor barite and sulfide ore zone is still active, although black smoker activity does not occur on the seafloor. The recovered drill core shows that the subseafloor deposit is zoned with depth. The top of the mineralized zone is comprised of a variably silicified vuggy barite-sulfide facies that shows notable polymetallic metal enrichment, while the deeper portion of the mineralized zone is dominated by massive pyrite having distinctly lower base and precious metal grades. Metal zonation of the barite and sulfide deposit is related to the evolution of the hydrothermal fluids in space and time. The barite cap and the massive pyrite present in the deeper portion of the mineralized zone appear to have formed early in the paragenesis. During the main stage of the mineralization, the barite cap was brecciated and cemented by a polymetallic assemblage of barite and pyrite with minor chalcopyrite and tetrahedrite, trace famatinite, and rare cinnabar. Lower temperature precipitates formed during the main stage of mineralization include sphalerite, galena, pyrite, opal-A, and barite, which are associated with traces of Pb-Sb-As sulfosalts such as bournonite-seligmannite, or semseyite. A distinct mineral assemblage of fine-grained anhedral enargite, hypogene covellite, chalcopyrite, and galena is commonly associated with colloform sphalerite, galena, and pyrite as a late phase of this main stage. Colloform pyrite and marcasite are the last sulfides formed in the paragenetic sequence. The deposit is interpreted to have formed from fluids having an intermediate-sulfidation state, although excursions to high- and very high sulfidation states are indicated by the presence of abundant enargite and hypogene covellite. Laser ablation and conventional sulfur isotope analyses show that pyrite formed close to the seafloor within the zone of polymetallic metal enrichment has a variable sulfur isotope composition (δ34S = −39 to +3‰), whereas a more narrow range is observed in the massive pyrite at depth (δ34S = −10 to 0‰). Similar variations were also documented for the late native sulfur overprint. Overall, the negative sulfur isotope ratios at depth, the intermediate- to very high sulfidation conditions during mineralization, and the abundance of native sulfur suggest contributions of magmatic volatiles to the mineralizing fluids from a degassing magma chamber at depth. Biological processes are interpreted to have played a major role during late stages of ore formation. The combination of a subseafloor replacement deposit with a massive to semimassive barite cap rock overlying massive pyrite, the intermediate- to high-sulfidation characteristics, and the strong biological influence on the late stages of mineralization are distinct from other modern seafloor massive sulfide deposits and represents a style of submarine mineralization not previously recognized in a modern volcanic arc environment. The barite and sulfide occurrence at Palinuro shares many characteristics with porphyry-related base metal veins and intermediate-sulfidation epithermal deposits, suggesting that metallogenic processes associated with arc-related magmatic-hydrothermal systems are not restricted to the subaerial environment.

Type: Article , PeerReviewed

Format: text

DOI: 10.2113/econgeo.109.8.2129

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Modern sea-floor massive sulfides and base metal resources: Toward an estimate of global sea-floor massive sulfide potential (2010)

Hannington, Mark D. ; Jamieson, J. ; Monecke, Thomas ; [et al.]

Society of Economic Geologists

In: In: The Challenge of Finding New Mineral Resources: Global Metallogeny, Innovative Exploration, and New Discoveries. Vol. 2: Zinc-Lead, Nickel-Copper-PGE, and Uranium. , ed. by Goldfarb, R. J., Marsh, E. E. and Monecke, T. Special publications of the Society of Economic Geologists (15). Society of Economic Geologists, Littleton, Colorado, pp. 317-338.

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Publication Date: 2014-01-28

Type: Book chapter , NonPeerReviewed

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The minor element endowment of modern sea-floor massive sulfide deposits and comparison with deposits hosted in ancient volcanic successions (2016)

Monecke, Thomas ; Petersen, Sven ; Hannington, Mark D. ; [et al.]

Society of Economic Geologists

In: In: Rare Earth and Critical Elements in Ore Deposits. , ed. by Verplanck, P. L. and Hitzman, M. W. Reviews in Economic Geology, 18 . Society of Economic Geologists, Knoxville, Tenn., pp. 245-306. ISBN 978-1-62949-218-6

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Publication Date: 2017-03-22

Description: Sea-floor massive sulfide deposits represent a new type of base and precious metal resources that may be exploited by future deep-sea mining operations. These deposits occur in diverse tectonic environments and are mostly located along the global mid-ocean ridge system within international waters and arc-related settings within the exclusive economic zones of the world’s oceans. Much controversy is currently centered on the question whether sea-floor massive sulfide deposits represent a significant resource of metals that could be exploited to meet the metal demand of modern technology-based society. Chemical analysis of sulfide samples from sea-floor hydrothermal vent sites worldwide shows that sea-floor massive sulfides can be enriched in the minor elements Bi, Cd, Ga, Ge, Hg, In, Mo, Sb, Se, Te, and Tl, with concentrations ranging up to several tens or hundreds of parts per million. The minor element content of seafloor sulfides broadly varies with volcanic and tectonic setting. Massive sulfides on mid-ocean ridges commonly show high concentrations of Se, Mo, and Te, whereas arc-related sulfide deposits can be enriched in Cd, Hg, Sb, and Tl. Superposed on the volcanic and tectonic controls, the minor element content of sea-floor sulfides is strongly influenced by the temperature-dependent solubility of these elements. The high- to intermediatetemperature suite of minor elements, Bi, In, Mo, Se, and Te, is typically enriched in massive sulfides composed of chalcopyrite, while the low-temperature suite of minor elements, Cd, Ga, Ge, Hg, Sb, and Tl, is more typically associated with sphalerite-rich massive sulfides. Temperature-related minor element enrichment trends observed in modern sea-floor hydrothermal systems are broadly comparable to those encountered in fossil massive sulfide deposits. Although knowledge on the mineralogical sequestration of the minor elements in sea-floor massive sulfide deposits is limited, a significant proportion of the total amount of minor elements contained in massive sulfides appears to be incorporated into the crystal structure of the main sulfide minerals, including pyrite, pyrrhotite, chalcopyrite, sphalerite, wurtzite, and galena. In addition, the over 80 trace minerals recognized represent important hosts of minor elements in massive sulfides. As modern sea-floor sulfides have not been affected by metamorphic recrystallization and remobilization, the minor element distribution and geometallurgical properties of the massive sulfides may differ from those of ancient massive sulfide deposits. The compilation of geochemical data from samples collected from hydrothermal vent sites worldwide now permits a first-order evaluation of the global minor element endowment of sea-floor sulfide deposits. Based on an estimated 600 million metric tons (Mt) of massive sulfides in the neovolcanic zones of the world’s oceans, the amount of minor elements contained in sea-floor deposits is fairly small when compared to land-based mineral resources. Although some of the minor elements are potentially valuable commodities and could be recovered as co- or by-products from sulfide concentrates, sea-floor massive sulfide deposits clearly do not represent a significant or strategic future resource for these elements.

Type: Book chapter , NonPeerReviewed

Format: text

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