South Mathiatis: An unusual volcanogenic sulphide deposit in the Troodos ophiolite of Cyprus

References

• Adamides NG. 1984. Cyprus volcanogenic sulphide deposits in relation to their environment of formation, PhD thesis, University of Leicester, UK.
   Google Scholar
• Adamides NG. 2007. A further report on the South Mathiatis deposit, with a revised resource estimation, internal report, EMED Mining Public Ltd, UK.
   Google Scholar
• Barton P. Bethke B., P.M and Roedder E. 1977. Environment of ore deposition in the Creede mining district, San Juan mountains, Colorado: Part III. Progress toward interpretation of the chemistry of the ore-forming fluid for the OH vein, Econ. Geol., 72, 1–24.
   Web of Science ®Google Scholar
• Barton PB and Bethke PM. 1987. Chalcopyrite disease in sphalerite: Pathology and epidemiology, Am. Mineral., 72, 451–467.
   Web of Science ®Google Scholar
• Bear LM. 1960. The geology and mineral resources of the Akaki–Lythrodondha area: Memoir 3, Geolog. Surv. Depart., Cyprus.
   Google Scholar
• Bear LM. 1963. The mineral resources and mining industry of Cyprus: Bull. No. 1, Geol. Surv. Dept., Cyprus.
   Google Scholar
• Bishop JR and Emerson DW. 1999. Geophysical properties of zinc-bearing deposits, Aust. J. Earth Sci., 3, 311–328.
   Web of Science ®Google Scholar
• Boyce AJ, Little CTS and Russell MJ. 2003. A new fossil vent biota in the Ballynoe barite deposit, Silvermines, Ireland: Evidence for intracratonic sea-floor hydrothermal; activity about 352 Ma, Econ. Geol., 98, 649–656.
   Web of Science ®Google Scholar
• Christoforou YN. 1974. Geochemical survey at Mathiatis (Mitsero), Internal Report, Hellenic Mining Company Ltd, Nicosia, Cyprus.
   Google Scholar
• Christoforou YN. 1975. Cupriferous sulphide mineralisation of the Kokkinoyia mine. Unpublished Master’s dissertation, Cardiff, UK.
   Google Scholar
• Constantinou G and Govett GJS. 1973. Geology, geochemistry and genesis of Cyprus sulfide deposits, Econ. Geol., 68, 843–858.
   Web of Science ®Google Scholar
• Deer WW, Howie RA and Zussman J. 1966. An introduction to the rock-forming minerals, 1st edn, London, Longmans, Green and Co. Ltd.
   Google Scholar
• Duhig NC, Stolz J, Davidson GJ and Large RR. 1992a. Cambrian microbial and silica gel textures in silica iron exhalites from the Mount Windsor volcanic belt, Australia: Their petrography, chemistry and origin, Econ. Geol., 87, 764–784.
   Web of Science ®Google Scholar
• Duhig NC, Davidson GJ and Stolz J. 1992b. Microbial involvement in the formation of Cambrian sea-floor silica–iron oxide deposits, Australia, Geology, 20, 511–514.
   Web of Science ®Google Scholar
• Emerson D and Moyer CL. 2002. Neutrophilic Fe-oxidising bacteria are abundant at the Loihi seamount hydrothermal vents and play a major role in Fe oxide deposition, Appl. Environ. Microb., 3085–3093.
   Web of Science ®Google Scholar
• Franklin JM, Lydon JW and Sangster DF. 1981. Volcanic-associated massive sulfide deposits, Econ. Geol., Seventy-fifth Ann. Vol., 485–627.
   Google Scholar
• Galley A, Hannington M and Jonasson I. 2007. Volcanogenic massive sulphide deposits, in Mineral deposits of Canada: A synthesis of major deposit-types, District metallogeny, the evolution of geological provinces, and exploration methods, (ed. Goodfellow W D), 141–162, Min. Dep. Div. Spec. Pub. 5, Geolog. Assoc. Canada.
   Google Scholar
• Gass IG and Masson-Smith D. 1963. The geology and gravity anomalies of the Troodos Massif, Philos. Trans. R. Soc. Lond., A255, 417–467.
   Web of Science ®Google Scholar
• Grenne T and Slack JF. 2003. Paleozoic and Mesozoic silica-rich seawater. Evidence from hematitic chert (jasper) deposits, Geology, 31, 319–322.
   Web of Science ®Google Scholar
• Hall JM. 1987. Interaction of submarine volcanic and high-temperature hydrothermal activity proposed for the formation of the Agrokipia volcanic massive sulfide deposits of Cyprus, Can. J. Earth Sci., 29, 1928–1936.
   Google Scholar
• Hannington MD, Humphris SE, Galley AG, Herzig PM and Petersen S. 1998. Comparison of the Tag mound and stockwork complex with Cyprus-type massive sulfide deposits, Proc. Ocean Dril. Program, Sci. Results, 158, 389–415.
   Google Scholar
• Haymon RM. 1982. Hydrothermal deposition on the East Pacific Rise, at 21° N, unpublished PhD thesis, University of California, San Diego, CA, USA.
   Google Scholar
• Herzig PM. 1988. A mineralogical, geochemical and thermal profile through the Agrokipia B hydrothermal sulfide deposit, Troodos ophiolite complex, Cyprus, in Base metal sulfide deposits (ed. Friedrich G H and Herzig P M), 182–215, Berlin, Heidelberg, Springer Verlag.
   Google Scholar
• Herzig PM and Hannington MD. 1995. Polymetallic massive sulfides at the modern ocean seafloor: A review, Ore Geol. Rev., 10, 95–115.
   Web of Science ®Google Scholar
• Hopkinson L, Roberts S, Herrington R and Wilkinson J. 1998. Self-organisation of submarine hydrothermal siliceous deposits: evidence from the TAG hydrothermal mound, 26° N Mid-Atlantic Ridge, Geology, 26, 347–350.
   Web of Science ®Google Scholar
• Hopkinson L, Roberts S, Herrington R and Wilkinson J. 1999. The nature of crystalline silica from the TAG submarine hydrothermal mount, 26° N Mid-Atlantic Ridge, Contrib. Mineral. Petrol., 137, 342–350.
   Web of Science ®Google Scholar
• Hutchinson RW and Searle DL. 1971. Stratabound pyrite deposits in Cyprus and relations to other sulphide ores, Soc. Min. Geol. Jpn, Special Issue 3, 198–205.
   Google Scholar
• Jorge RCGS, Relvas JMRS and Barriga FJAS. 2005. Silica gel microstructures in siliceous exhalites at the Soloviejo manganese deposit, Spain, Abstracts of SGA Meeting, Beijing, China, August, Session 6–9, 631–634.
   Google Scholar
• Juniper SK and Fouquet Y. 1988. Filamentous iron-silica deposits from modern and ancient hydrothermal sites, Can. Mineral., 26, 859–869.
   Web of Science ®Google Scholar
• Kalogeropoulos SI. 1985. Discriminant analysis for evaluating the use of lithogeochemistry along the Tetsusekiei Horizon as an exploration tool in search for Kuroko type ore deposits, Min. Depos., 20, 135–142.
   Web of Science ®Google Scholar
• Kalogeropoulos SI and Scott SD. 1983. Mineralogy and geochemistry of tuffaceous exhalites (tetsusekiei) of the Fukazawa mine, Hokuroku district, Japan, Econ. Geol. Mon. 5, 412–432.
   Google Scholar
• Koski RA, Clague DA and Oudin E. 1984. Mineralogy and chemistry of massive sulfide deposits from the Juan de Fuca Ridge, Bull. Geol. Soc. Am., 95, 930–945.
   Web of Science ®Google Scholar
• Maliotis G. 1978. Applicability and limitations of the IP in Cyprus, unpublished PhD thesis, University of Leicester, UK.
   Google Scholar
• Moores EM and Vine FJ. 1971. The Troodos massif, Cyprus, and other ophiolites as oceanic crust: evaluation and implications, Philos. Trans. R. Soc. Lond., 268, 443–466.
   Web of Science ®Google Scholar
• Rona PA. 1978. Criteria for recognition of hydrothermal mineral deposits in oceanic crust, Econ. Geol., 73, 135–160.
   Web of Science ®Google Scholar
• Rona PA. 2005. TAG hydrothermal field: A key to modern and ancient seafloor hydrothermal VMS ore-forming systems, Abstracts of SGA Meeting, Beijing, China, August, 6–23, 687–690.
   Google Scholar
• Robinson PT, Melson WG, O’Hearn T and Schmincke H-U. 1983. Volcanic glass compositions of the Troodos ophiolite, Cyprus, Geology, 11, 400–404.
   Web of Science ®Google Scholar
• Solomon M and Walshe JL. 1979. The formation of massive sulfide deposits on the sea floor, Econ. Geol., 74, 797–813.
   Web of Science ®Google Scholar
• Varga RJ and Moores EM. 1985. Spreading structure of the Troodos ophiolite, Cyprus, Geology, 13, 846–850.
   Web of Science ®Google Scholar