A transition from gabbro to eclogite has been investigated at Vinddøldalen in south-central Norway, with the aim to link reaction textures to metamorphic zircon growth and to obtain a direct U–Pb zircon age of the metamorphic process. In the different rocks of the transition zone zircon occurs as (I) igneous prismatic grains, (II) metamorphic polycrystalline rims and pseudomorphs after baddeleyite, and (III) as tiny (<10 µm) bead-like zircon grains. Textural relations suggest that type II zircon formed by breakdown of baddeleyite in the presence of silica, whereas Fe–Ti oxides were the main Zr source for the type III zircon. Subsolidus liberation of Zr and formation of bead zircon took place by oxyexsolution of titanomagnetite during fluid-assisted metamorphism, and by resorption of Fe–Ti oxide in rock domains that were completely recrystallized to eclogite. SIMS (secondary ion mass spectrometry) and TIMS (thermal ionization mass spectrometry) dating provides comparable U–Pb ages of magmatic zircon and baddeleyite. Baddeleyite (TIMS) yielded an age of 1457±11 Ma for the gabbro emplacement. Bead-type metamorphic zircon from eclogite gave 425±10 Ma (TIMS) dating the metamorphic transition from gabbro to eclogite in the upper basement of the Lower Allochthon in the south-central Scandinavian Caledonides.
U–Pb zircon dates of metagabbroic rocks, such as eclogite, mafic granulite, and garnet amphibolite, are used to constrain the timing of tectonometamorphic evolution in orogens worldwide. For such interpretation, however, it is imperative to define at which stage of the P–T evolution that zircon crystallization took place: the prograde, peak, or retrograde stage. In order to accurately interpret metamorphic zircon ages, it is necessary to assess how the zircon crystallized or recrystallized, as zircon can dissolve or grow under different metamorphic conditions. Zircon is robust to retrograde isotopic resetting under most crustal conditions, but equilibrium Zr mass balance models have suggested that zircon is largely produced during retrograde metamorphism. This study takes a textural approach and identifies and reviews zircon‐forming textures and reactions in gabbro and metagabbro at different metamorphic grades, ranging from subgreenschist to upper amphibolite‐ and eclogite‐facies, and at different stages of metamorphic recrystallization. The textural relationships demonstrate that, in metagabbro, metamorphic zircon grows during the early stage of metamorphic recrystallization, independent of pressure and temperature. The mode of zircon formation is remarkably similar throughout different stages of metamorphic recrystallization, and the most significant source of Zr is igneous baddeleyite. Hence, in contrast to the equilibrium mass balance model, most zircon in metagabbro forms by prograde metamorphic reactions that consume igneous phases, and not by late retrograde reactions, and the onset of zircon forming reactions is governed primarily by the introduction of a hydrous fluid, commonly accompanied by ductile deformation.
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