Abstract
This important class of ore deposits is the source of most of the world’s metals. Hydrothermal deposits provide almost 100% of our Pb, Zn, Mo, and Ag, 60–90% of our Cu, Au and U, as well as gemstones and industrial materials such as clay minerals and quartz. Hydrothermal deposits are diverse, being present in a wide range of geological settings and tectonic environments: some are closely associated with granitic intrusions, others form on the ocean floor and still others are in sedimentary basins. What all the deposits have in common is their origin via the precipitation of metals or ore minerals from hot aqueous fluids.
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Barnes HL (1979) Geochemistry of hydrothermal ore deposits. Wiley, New York, 997 pp
Brimhall GH, Crerar DA (1987) Ore fluids: magmatic to supergene. Rev Mineral Geochem 17:235–321
Cathles LM, Adams JJ (2005) Fluid flow and petroleum and mineral resources in the upper (<20 km) continental crust. Econ Geol 100th Anniversary Volume:77–110
Chenovoy M, Piboule M (2007) Hydrothermalisme. Spéciation métallique hydrique et systèmes hydrothermaux. Collection Grenoble Sciences 624 pp
Dubé, B. and Gosselin, P. 2008, Mineral Deposits of Canada - greenstone-hosted quartz-carbonate vein deposits. http://gsc.nrcan.gc.ca/mindep/synth_dep/gold/greenstone/index_e.php.
Ellis A.J., (1979) Explored geothermal systems. In H.L. Barnes (Ed.), Geochemistry of hydrothermal ore deposits, 2nd ed. : 632–683. Wiley & Sons
Evans AN (1993) Ore geology and industrial minerals: an introduction. Blackwell, Oxford, 390 pp
Franklin, JM and Gibson, HL and Jonasson, IR and Galley, AG (2005) Volcanogenic massive sulfide deposits. Economic Geology 100th Anniversary Volume, pp 523–560
Goodfellow WD, Lydon JW (2007) Sedimentary exhalative (SEDEX) deposits. In: Goodfellow WD (ed), Mineral deposits of Canada: Geological Association of Canada. Special Publication No. 5, pp 163–183
Hannington MD, Galley AG, Herzig PM, Petersen S (1998) Comparison of the TAG mound and stockwork complex with Cyprustype massive sulfide deposits. In: Proceedings of the Ocean Drilling Program, Scientific Results Volume 158, College Station, pp 389–415
Hedenquist J.W., Henley R.W., (1985) Hydrothermal eruptions in the Waiotapu geothermal system, New Zealand: origin, breccia deposits and effect of precious metal mineralization. Economic Geology (80) : 1640–1666.
Herrington, R., Maslennikov, V., Zaykov, V., Seravkin, I., Kosarev, A., Buschmann, B., Orgeval, J.J., Holland, N., Tesalina, S., Nimis, P., Armstrong, R. (2005) Classification of VMS deposits: Lessons from the South Uralides. Ore Geology Reviews (27), pp203–237. doi:10.1016/j.oregeorev.2005.07.014
Krupp R.E., Seward T.M., (1987) The Rotokawa geothermal system, New Zealand: an active epithermal gold-depositing environment. Economic Geology (82) 1109–1129
Jefferson CW, Thomas DJ, Gandhi SS, Ramaekers P, Delaney G, Brisbin D, Cutts C, Quirts D, Portella P, Olson RA (2008) Unconformity associated uranium deposits. In: Goodfellow WD (ed), Mineral deposits of Canada: Geological Association of Canada. Special Publication No. 5, pp 273–305
Lowell JD, Gilbert JM (1970) Lateral and vertical alteration-mineralization zoning in porphyry ore deposits. Econ Geol 65:373–408
Ossandon CG, Freraut RC, Gustafson LB, Lindsay DD, Zentilli M (2001) Geology of the Chuquicamata mine: a progress report. Econ Geol 96(2):249–270. doi:10.2113/96.2.249 DOI:dx.doi.org
Robb LJ (2005) Introduction to ore-forming processes. Blackwell, Malden, 373 pp
Sillitoe RH (2010) Porphyry copper systems. Econ Geol 105:3–41
Sinclair WD (2007) Porphyry deposits. In: Goodfellow WD (ed), Mineral deposits of Canada: a synthesis of major deposit-types, district metallogeny, the evolution of geological provinces, and exploration methods: Geological Association of Canada. Special Publication No. 5, pp. 223–243
Simmons S.F., Browne P.R., (2000) Hydrothermal minerals and precious metals in the Broadlands-Ohaaki geothermal system: implications for understanding low-sulfidation epithermal environments. Economic Geology (95) 971–999
Von Damm K.L., (1990) Seafloor hydrothermal activity: black smoker chemistry and chimney. Annual Reviews of Earth and Planetary sciences (18) 173–204
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Arndt, N., Ganino, C. (2011). Hydrothermal Deposits. In: Metals and Society. Metals and Society, vol 2. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-22996-1_4
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DOI: https://doi.org/10.1007/978-3-642-22996-1_4
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