Mineralogical Study of the Advanced Argillic Alteration Zone at the Konos Hill Mo–Cu–Re–Au Porphyry Prospect, NE Greece

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Authors

  • Costantinos Mavrogonatos,
  • Panagiotis Voudouris
  • Paul G. Spry
  • Vasilios Melfos
  • Stephan Klemme
  • Jasper Berndt
  • Tim Baker
  • Robert Moritz
  • Thomas Bissig
  • Thomas Monecke

External Organisational units

  • National and Kapodistrian University of Athens Department of Economics Domain of Mathematics and Informatics
  • Department of Mechanical and Industrial Engineering
  • Aristotle University of Thessaloniki
  • Westfälische Wilhelms-Universität Münster
  • Eldorado Gold Corporation, Vancouver
  • Department of Earth Sciences
  • Colorado School of Mines
  • Goldcorp Inc., Vancouver

Abstract

The Konos Hill prospect in NE Greece represents a telescoped Mo–Cu–Re–Au porphyry occurrence overprinted by deep-level high-sulfidation mineralization. Porphyry-style mineralization is exposed in the deeper parts of the system and comprises quartz stockwork veins hosted in subvolcanic intrusions of granodioritic composition. Ore minerals include pyrite, molybdenite, chalcopyrite, and rheniite. In the upper part of the system, intense hydrothermal alteration resulted in the formation of a silicified zone and the development of various advanced argillic alteration assemblages, which are spatially related to N–S, NNW–SSE, and E–W trending faults. More distal and downwards, advanced argillic alteration gradually evolves into phyllic assemblages dominated by quartz and sericite. Zunyite, along with various amounts of quartz, alunite, aluminum phosphate–sulfate minerals (APS), diaspore, kaolinite, and minor pyrophyllite, are the main minerals in the advanced argillic alteration. Mineral-chemical analyses reveal significant variance in the SiO2, F, and Cl content of zunyite. Alunite supergroup minerals display a wide compositional range corresponding to members of the alunite, beudantite, and plumbogummite subgroups. Diaspore displays an almost stoichiometric composition. Mineralization in the lithocap consists of pyrite, enargite, tetrahedrite/tennantite, and colusite. Bulk ore analyses of mineralized samples show a relative enrichment in elements such as Se, Mo, and Bi, which supports a genetic link between the studied lithocap and the underlying Konos Hill porphyry-style mineralization. The occurrence of advanced argillic alteration assemblages along the N–S, NNW–SSE, and E–W trending faults suggests that highly acidic hydrothermal fluids were ascending into the lithocap environment. Zunyite, along with diaspore, pyrophyllite, and Sr- and Rare Earth Elements-bearing APS minerals, mark the proximity of the hypogene advanced argillic alteration zone to the porphyry environment.

Details

Original languageEnglish
Article number479
Number of pages18
JournalMinerals
Volume8.2018
Issue number11
DOIs
Publication statusPublished - 24 Oct 2018