Abstract
The Tertiary Skaergaard intrusion, East Greenland, intruded at the shallow crustal unconformity between Precambrian amphibolite-facies gneisses and overlying Tertiary Plateau Basalts. Maximum contact metamorphic temperatures in quartzo-feldspathic gneisses were determined in two sample traverses across the aureole on the western contact of the intrusion using a combination of microstructural observations (both optical and cathodoluminescence) and the titanium-in-quartz (TitaniQ) thermometer. The onset of recrystallization of the quartz in the gneisses occurred between 390 and 340 m from the contact whereas H2O-fluxed melting occurred in gneisses closer than 130 m from the contact (where T > ∼ 675°C). The maximum temperature recorded by quartz at the contact is ∼865 ± 70°C. Melt fractions reach 50–60 vol. % in some samples although the melt is heterogeneously distributed on all scales. Minor bands of amphibolite-facies mafic gneiss are extensively reacted to an anhydrous pyroxene-bearing hornfels close to the contact, whereas those further than ∼130 m are overprinted by a greenschist-facies assemblage. Discrepancies between the expected temperature for the amphibolite- to greenschist-facies reaction and temperatures obtained from adjacent quartzo-feldspathic gneisses are consistent with the formation of the anhydrous pyroxene hornfels directly from the mafic gneiss, with the lower-grade greenschist-facies assemblage forming on the retrograde path after the establishment of limited hydrothermal activity. It is unlikely that devolatilization reactions in the gneiss produced sufficient H2O to account for the pegmatitic features formed in the Marginal Border Series in the intrusion. A simple one-dimensional thermal model, neglecting any advection of heat by hydrothermal circulation, was fitted to the profile of maximum temperature through the aureole. The generally lower temperatures seen in the gneiss compared with those previously reported for the contact metamorphosed basalts higher up the walls of the intrusion are consistent with a heterogeneous release of latent heat of crystallization.
Highlights
Determining the thermal history of igneous intrusions is an essential step in constraining the time-scales controlling magma fractionation, eruptive behaviour, the formation of ore deposits and the thermodynamics of natural mineral assemblages
The Tertiary Skaergaard intrusion is situated on the east coast of Greenland and comprises c. 280 km3 of basaltic magma that intruded at a shallow crustal unconformity between Precambrian gneisses and overlying Tertiary flood basalts into a fault-bounded magma chamber (Nielsen, 2004) (Fig. 1)
Comparison with the aureole developed in the basalts Maximum temperatures Two-pyroxene thermometry in the pyroxene zone of the aureole formed in the basaltic country rocks on the eastern margin of the intrusion (Manning et al, 1993) yields maximum temperatures of $9008C (Fig. 13) at the contact, decreasing to $8008C 250 m away
Summary
Determining the thermal history of igneous intrusions is an essential step in constraining the time-scales controlling magma fractionation, eruptive behaviour, the formation of ore deposits and the thermodynamics of natural mineral assemblages. We describe the effects of contact metamorphism on subordinate mafic bands in the gneisses to assess the extent to which they might have supplied H2O to flux melting in the adjacent quartzo-feldspathic material and to examine the hypothesis that the country rocks supplied significant quantities of H2O to the marginal regions of the intrusion (Irvine et al, 1998). These bands are continuous over many tens of metres and are 0·5^20 m thick. Sampling took place during two separate field seasons (2008, 2011), permitting the location of important microstructural developments to be pinpointed
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