Franklin, James M. (2002): Seafloor minerals research; supporting discovery of new ore deposits

Leg/Site/Hole:
ODP 139
ODP 169
ODP 111 504
ODP 137 504
ODP 140 504
ODP 148 504
Identifier:
2005-008990
georefid

Creator:
Franklin, James M.
Franklin Geosciences, Ottawa, ON, Canada
author

Identification:
Seafloor minerals research; supporting discovery of new ore deposits
2002
In: Anonymous, Geological Society of America, 2002 annual meeting
Geological Society of America (GSA), Boulder, CO, United States
34
6
444-445
Mineralizing processes at seafloor hydrothermal sites are directly observed and measured, reducing uncertainties inherent in interpretation of ancient, deformed and metamorphosed ore-bearing districts. The best example is volcanogenic massive sulfide (VMS) deposits. For these, seawater is down-drawn regionally to cool shallow crustal-level subvolcanic intrusions; these provide heat and drive convective circulation beneath caps which inhibit cross-stratal fluid migration. Trapped fluids reach approximately 400C and react with their enclosing strata, imparting a unique mineralogical imprint on the latter and releasing metals to the fluid. Fluids discharge in convective upwelling zones or along caldera- or rift-margin extensional faults. Near-seafloor reactions form distinct alteration pipes. Fluids discharge on or near the seafloor, where rapid cooling induces massive precipitation. Seafloor research contributes as follows: Magma-chamber petrochemical processes are unique to these environments, as shown by the specific occurrence of andesite (Galapagos VMS site). Identification of such petrochemically-unique units helps refine the land-based search in frontier areas. The ODP drill program (Legs 139 & 169; hole 504B) contributed to our knowledge of the reaction zone attributes; Site 857 at Middle Valley provided unequivocal mineralogical and compositional measures that now are applied in ancient sequences. Subseafloor alteration pipes establish sectoral and temporal variations in discharge-zone mineral and chemical attributes(Galapagos, TAG); these provide useable guides to ore in ancient pipes. The volcanological characteristics of caldera (Axial) and rift-related (Endeavour, EPR) synvolcanic faults provide a template for understanding similar preserved sequences. Finally, studies of vent fluids provide knowledge of metal speciation and predict characteristics such as gold contents (Axial, Lau, Havre Trough), sub-seafloor depositional and zone-refining attributes (ODP:TAG & Middle Valley), and far-field vectors from plume fallout. As research extends to new environments (arcs and backarcs) and to greater sub-seafloor depths (proposed TAG and other ODP sites) we will develop new, quantitative exploration guides that will be applied in searching for increasingly scarce mineral resources.
English
Coverage:Geographic coordinates:
North:48.2800
West:-128.4500East: -44.4900
South:-1.3000

Economic geology, general, deposits; alteration; Atlantic Ocean; back-arc basins; basins; chemical reactions; cooling; discharge; DSDP Site 504; East Pacific Ocean Islands; extension faults; faults; Galapagos Islands; intrusions; Leg 139; Leg 169; magma chambers; magmas; massive deposits; massive sulfide deposits; measurement; metal ores; Mid-Atlantic Ridge; Middle Valley; mineral exploration; mineral resources; mineralization; North Atlantic; observations; Ocean Drilling Program; ocean floors; precipitation; processes; quantitative analysis; research; sea water; TAG hydrothermal field; temperature; upwelling; variations;

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