Oxygen and carbon isotopic constraints on the development of eclogites, Holsnøy, Norway

Eclogite formation on the island of Holsnøy required the addition of water to anhydrous granulite-facies protoliths. In order to assess this process, oxygen and carbon isotope ratios of whole rock powders and mineral separates from eclogites and granulites have been measured. Whole rock oxygen isotope ratios range from 7.3 to 6.0%. SMOW in granulites (average = 6.38%.) and 7.2 to 6.1%. in eclogites (average = 6.55%.). Field relations permit identification of the granulite protolith of eclogites. Oxygen isotope measurements show shifts of up to 0.5%. between some eclogites compared to their corresponding granulite protoliths, indicating open system and locally heterogeneous fluid behavior. Mineral pair fractionations in the eclogites show disequilibrium, are incompatible with slow cooling and diffusive exchange between phases, and suggest that open system fluid movement continued after eclogite-facies metamorphism. Carbonate is also present in some of the eclogites as a primary mineral (dolomite) and as part of a retrograde assemblage (calcite). Textural evidence suggests that carbonate formation occurred during and after eclogite formation, however all measured carbonate is out of isotopic equilibrium with eclogite facies minerals, due to the influx of retrograde fluids. Massive calcite marble pods, containing amphibolite facies cale-silicate minerals, have average δ¹⁸O of 9.5 ± 0.6%., while calcite in retrograded eclogites has δ¹⁸O 17.7 ± 2.7%., The δ¹³C (≈ ?4 ± 0.8%.) is indistinguishable between these two groups.

Both whole rock and carbonate stable isotope data are interpreted as indicating a continued history of fluid infiltration during and after peak eclogite facies metamorphism. The most probable source of fluids are from dewatered sediments tectonically juxtaposed during the Caledonian orogeny.