Late Archean Lake Harris Komatiite, Central Gawler Craton, South Australia:Geologic Setting and Geochemistryстатья из журнала
Аннотация: The Lake Harris Komatiite in the central Gawler craton of South Australia is
the first documented komatiite outside the West Australian craton and the
easternmost occurrence of such primitive ultramafic rocks in Australia. A U-Pb
zircon age of ca. 2520 Ga for the komatiitic sequence indicates a previously
unknown period of mantle-plume activity in the Late Archean. An integrated
program of airborne magnetic surveys, gravity surveys, and core drilling was
successful in defining the distribution and volcanic architecture of the
komatiitic flows and associated greenstones through an extensive thin cover of
Cenozoic alluvial sediments. Surface exposure of the komatiitic rocks is
restricted to one small outcrop near Lake Harris. The greenstones form a series
of subparallel east-northeast–trending sinuous magnetic highs flanked by large
ovoid to elongate magnetic highs and lows that correlate with
Archean-Proterozoic granitic bodies associated with province-wide shear systems,
similar to the Archean greenstone terranes in the Yilgarn craton of Western
Australia. The steeply dipping greenstone sequence was metamorphosed to middle
amphibolite facies during the ca. 2440 Ma Sleafordian orogeny and sheared during
the ca. 1700 Ma Kimban and ca. 1540 Ma Kararan orogenies. The greenstones
consist of komatiite cumulates (43–32% MgO, anhydrous), high to low Mg
komatiite (32–18% MgO), komatiitic and tholeiitic basalt (<18% MgO),
pyroxenite cumulates, felsic volcanic rocks, minor metasedimentary rocks,
pyroclastic rocks, and rare banded iron formation. They extend over 300 km in
three subparallel belts that appear to be isoclinally folded around
east-northeast axes and tectonically dismembered to the south by the Yerda shear
zone. Komatiitic rocks have been confirmed by drilling in all three belts, but
the absence of outcrop and structural complexities prevent detailed
stratigraphic correlations within and between the belts. The komatiitic rocks display a range of quenched and cumulus textures defined
by the different habits of olivine and its alteration products. Trace sulfides (pyrrhotite,
chalcopyrite, pentlandite, pyrite, marcasite, polydymite violarite,
heazelwoodite, millerite) form very small (0.01–0.2 mm) single-phase
disseminated grains and coarser disaggregated grains. Their distribution largely
reflects metamorphic and serpentinization processes, with high Ni/S ratios and
probable sulfur loss from the more magnesian parts of the flows. Rare composite
pyrrhotite-pentlandite-chalcopyrite blebs (0.1–0.5 mm) characterize some low
Mg flows. Locally, there is supergene pyrite-marcasite and native
copper-bornite-chalcocite(?) assemblage infilling of late low-temperature
serpentine-chlorite veinlets. Thick ponded lava lake and distal composite sheet flow facies have been
identified from different parts of the komatiitic sequences. Systematic
whole-rock and mineral chemical trends indicate that despite the effects of
recrystallization and reequilibration during amphibolite-facies metamorphism,
the original magmatic geochemical profiles are largely preserved. The whole-rock
data for the Lake Harris Komatiite does not show any obvious Ni depletion during
fractionation but indicate a strong olivine control in dominantly sulfur
undersaturated environments. Low sulfur (100–600 ppm S) and high Pd + Pt (5–30
ppb) contents, and Ti/Pd ratios of 2 to 4 × 10 5 for the komatiitic
rocks are similar to sulfur-undersaturated Archean komatiites hosting Ni-Cu-PGE
deposits, i.e., there is little evidence for sulfur saturation in the sampled
komatiites. Identification of a pre-2.5 Ga source of sulfur in the substrate
would be a positive indicator of potential sulfur saturation of the lavas
elsewhere in the greenstone belt and a possible target for mineralization. The Lake Harris Komatiite has chemical (parent magma composition of 29% MgO,
Al 2 O 3 /TiO 2 = 16, depleted light (L)REE and
initial Nd isotope ( ϵ Nd = 2.8–3.0 at 2520 Ma)
characteristics similar to typical Al-depleted Archean komatiites, and there is
no clear evidence of chemical modification by processes associated with
contemporary subduction. Coherent patterns of trace elements (Th, Nb, REE, Ti,
Y, Zr, and P) and typical initial ϵ Nd signatures
indicate a Late Archean komatiitic system involving a depleted mantle source and
no obvious crustal contamination. This system probably exploited a lithosphere
that was stretched and thinned by extension and/or thermal erosion in an
intraplate environment. Dynamic tectonic environments involving mantle-plume
activity, long-lived active plate margins, and widespread arc volcanism during
the Late Archean are now favored for the evolution of the western Gawler craton.
Год издания: 2005
Авторы: D M Hoatson, Shen‐Su Sun, M. B. Duggan, M. B. Davies, S. J. Daly, A. C. Purvis
Источник: Economic Geology
Ключевые слова: Geological and Geochemical Analysis, earthquake and tectonic studies, High-pressure geophysics and materials
Открытый доступ: closed
Том: 100
Выпуск: 2
Страницы: 349–374