Chronology of the high-pressure metamorphism of Norwegian garnet peridotites/pyroxenites

Eclogite facies mineral assemblages are variably preserved in mafic and ultramafic rocks within the Western Gneiss Region (WGR) of Norway. Mineralogical and microstructural data indicate that some Mg–Cr-rich, Alpine-type peridotites have had a complex metamorphic history. The metamorphic evolution of these rocks has been described in terms of a seven-stage evolutionary model; each stage is characterized by a specific mineral assemblage. Stages II and III both comprise garnet-bearing mineral assemblages. Garnet-bearing assemblages are also present in Fe–Ti-rich peridotites which commonly occur as layers in mafic complexes. Sm–Nd isotopic results are reported for mineral and whole rock samples from both of these types of peridotites and related rocks. The partitioning of Sm and Nd between coexisting garnet and clinopyroxene is used to assess chemical equilibrium. One sample of Mg–Cr-type peridotite shows non-disturbed partitioning of Sm and Nd between Stage II garnet and clinopyroxene pairs and yields a garnet–clinopyroxene–whole-rock date of 1703 ± 29 Ma (I= 0.51069, MSWD = 0.04). This is the best estimate for the age of the Stage II high-P assemblage. Other Stage II garnet–clinopyroxene pairs reflect later disturbance of the Sm–Nd system and yield dates in the range 1303 to 1040 Ma. These dates may not have any geological significance. Stage III garnet–clinopyroxene pairs typically have equilibrated Sm–Nd partitioning and two samples yield dates of 437 ± 58 and 511 ± 18 Ma. This suggests that equilibration of the Stage III high-P assemblage is related to the Caledonian orogeny and is more or less contemporaneous with high-P metamorphism of ‘country-rock’eclogites in the surrounding gneisses. The Sm–Nd mineral data for the Fe–Ti-rich garnet peridotites and for a superferrian eclogite, which occurs as a dyke within the Gurskebotn Mg–Cr-type peridotite, are consistent with a Palaeozoic high-P metamorphism. Finally a synoptic P–T–t path is proposed for the Mg–Cr-type peridotites which is consistent with the petrological and geochronological data.     

VELOCITY ANALYSIS IN THE p—x-PLANE FROM A SLANT STACK WAVEFIELD*

Classical methods of interpretation of reflection seismic data are such that interpretation and processing usually occur in the “collected” frame of reference. However, in recent times other data planes have gained increasing acceptance in seismology as a viable alternative. Through linear transformations applied to a record section, both the t—p- and p—x-planes can be produced. The r—p-domain may be obtained from the t—x-plane by a transformation known as slant stacking. Normal practice has been to do most of the data processing in the t—x-plane and then transforming to the r—p-plane. However, many of the procedures used in the t—x-domain can be modified for use in the t—p-plane to increase the coherence. Velocity inversion may be carried out either in the r—p-domain or further transformed to the p—x-plane where the modified Herglotz-Wiechert inversion may be applied. To perform the inversion, the t—p-wavefield is converted to a p—x-representation by the use of a new linear transformation technique, the cross-stack. By a simple sampling process along a particular p—x-trajectory, the Herglotz-Wiechert method can be used to reconstruct an acceptable velocity model of the subsurface. A comparison of derived velocity structures is made between that produced by the Herglotz-Wiechert technique and that of the Dix method.     

A tectonic model for the metamorphic evolution of the Basal Gneiss Complex, Western South Norway

A review of currently available information relevant to the Basal Gneiss Complex (BGC) of Western South Norway, combined with the authors'own observations, leads to the following conclusions.
1. Most of the BGC consists of Proterozoic crystalline rocks and probably subordinate Lower Palaeozoic cover.
2. The last major deformation of these rocks was during the Caledonian orogeny and involved large-scale thrusting, recumbent folding and doming. The structural development of the BGC is closely tied in with that of the Caledonian allochthon.
3. The whole eclogite-bearing part of the BGC has suffered a high pressure metamorphism with conditions of between 550°C, 12.5 kbar (Sunnfjord) and about 750°C, 20 kbar (Møre og Romsdal) at the metamorphic climax.
4. This metamorphism was of Caledonian age, probably rather early in the Caledonian tectonic history of the BGC and is considered to have been a rather transient event.
By setting these conclusions in a framework provided by geophysical evidence for the deep structure of the crust in southern Norway we have constructed a geotectonic model to explain the recorded metamorphic history of the BGC. It is suggested that considerable crustal thickening was caused by imbrication of the Baltic plate margin during continental collision with the Greenland plate. This resulted in high pressure metamorphism in the resulting nappe stack. Progradation of the suture caused underthrusting of the Baltic foreland below the eclogite-bearing terrain causing it to emerge at the Earth's surface, aided by tectonic stripping and erosion.
Application of isostacy equations to the model shows that eclogites can be formed by in-situ metamorphism in crustal rocks and reappear at the land surface above a normal thickness of crust in a single orogenic episode of approximately 65-70 Ma duration.     

Thermobarometry and Geotectonic Significance of High-Pressure Granulites: Examples from the Moldanubian Zone of the Bohemian Massif in Lower Austria

Petrographic details together with mineral and whole-rock compositiondata are provided for acid-intermediate garnet granulites fromexposed granulite complexes in Lower Austria. Thermobarometricevaluation integrated with available isotopic age data indicatesthe initial equilibration of early Variscan ({small tilde}370Ma) high-pressure granulite assemblages at {small tilde}16 kbarand 1000C and their partial overprinting by retrograde assemblageswhich reflect the blocking of mineral exchange reaction equilibriaat {small tilde}6•5 kbar and 725C during subsequent Variscanuplift and cooling. These calculated P-T estimates, togetherwith general phase equilibria constraints and evidence frompreserved prograde coronitic reaction textures and garnet compositionalzoning profiles, indicate a clockwise P-T-t evolutionary pathof the type expected during crustal thickening in a major platecollision orogen and characterized by near-isothermal decompressionduring initial uplift. Geochemical characterization of the rockprotoliths as calc-alkaline igneous rocks and the high metamorphictemperatures suggest that garnet granulite formation involvedthe subduction of a magmatic arc at a continental plate margin. Reviewed evidence from granulites in the Central European Variscidesruns counter to suggestions by Bohlen (1987, 1991) that high-pressuregranulites are of little regional geotectonic significance incomparison with low- to medium-pressure granulites. The differentevolutionary P-T paths for these two important groups of granulitespoint to formation in contrasting plate settings. However, questionsare raised regarding petrogenetic models for low- to medium-pressuregranulites which have emphasized the importance of magmatic,rather than tectonic, crustal thickening and the recognitionof stabilization along deduced anti-clockwise P-T-t paths characterizedby post-peak near-isobaric cooling. It is suggested here that the reality of stabilization of atleast some low- to medium-pressure granulites in a collisionaltectonic regime may have been concealed either because lower-pressureassemblages have overprinted mineralogical evidence for an earlierhigh-pressure history at deeper crustal levels or through invaliddeduction of near-isobaric cooling trajectories as a resultof the different closure temperatures for the mineral reactionsused to monitor the equilibration temperatures and pressuresin granulites. However, the sequential underthrusting modelfavoured for the tectonometamorphic evolution of the Variscannappe pile in the Bohemian Massif renders it unlikely that alllate Variscan low- to medium-pressure granulites have experiencedthe early Variscan high-pressure metamorphism.     

Thermobarometry of phengite-bearing eclogites in the Dabie Mountains of central China

Pressure–temperature conditions for formation of the peak metamorphic mineral assemblages in phengite-bearing eclogites from Dabieshan have been assessed through a consideration of Fe²⁺–Mg²⁺ partitioning between garnet–omphacite and garnet–phengite pairs and of the reaction equilibrium celadonite+pyrope+grossular=muscovite+diopside, which incorporates an evaluation of the extent of the strongly pressure-dependent inverse Tschermak's molecule substitution in the phengites. For the latter equilibrium, the calibration and recommended activity–composition models indicated by 45 ) have been employed and importantly yield results consistent with petrographic evidence for the stability at peak conditions of coesite in certain samples and quartz in others. Confirmation that in some phengite-eclogite samples peak silicate mineral assemblages have equilibrated at confining pressures sufficient for the stability of coesite (and in some cases even diamond) rather negates previous suggestions that coesite may have been stabilized in only very localized, possibly just intracrystalline, domains. Inherent difficulties in the evaluation of peak metamorphic temperatures from Fe²⁺–Mg²⁺ partitioning between mineral phases, due to uncertainties over Fe³⁺/Fe²⁺ ratios in the minerals (especially omphacites), and to re-equilibration during extensive retrograde overprinting in some samples, are also assessed and discussed. Our results indicate the existence in south-central Dabieshan of phengite eclogites with markedly different equilibration conditions within two structurally distinct tectonometamorphic terranes. Thus our data do not support earlier contentions that south-central Dabieshan comprises a structurally coherent continental-crust terrane with a regional P–T gradient signalling previous deepest-level subduction in the north. Instead, we recognize the Central Dabie ultra-high-pressure (coesite eclogite-bearing) terrane to be structurally overlain by a Southern Dabie high-pressure (quartz eclogite-bearing) terrane at a major southerly dipping shear zone along which late orogenic extensional collapse appears to have eliminated at least 20 km of crustal section.     

Emplacement of Deep Upper-Mantle Rocks into Cratonic Lithosphere by Convection and Diapiric Upwelling

Rocks containing breakdown products of majoritic garnet, derivedfrom the deep upper mantle, occur in kimberlite xenoliths andin orogenic peridotites from Otrøy in Norway. The Otrøyperidotites are banded harzburgites and dunites with similarcompositions to mantle xenoliths from Precambrian cratons andPhanerozoic supra-subduction-zone peridotites. Pressure–temperature(P–T) paths deduced for the Otrøy peridotites andkimberlite xenoliths from South Africa are consistent with emplacementof deep mantle peridotites into cratonic lithosphere by asthenospherediapirism. Numerical thermo-convection models provide insightinto the possible P–T histories of deep upper-mantle rocks.In the models, material from the base of the convecting systemis transported to depths of 60–100 km by convection andsmall (50–100 km) diapirs. Diapir intrusion induces small-scaleconvection in the low-viscosity deeper part of the thermochemicallydefined lithosphere. Small-scale convection in the craton rootcan produce complex P–T paths, complex recurrent meltinghistories and complex compositional structure in the craton.P–T paths derived from the numerical models for asthenospherediapirism in a hot upper mantle are consistent with the sequenceof sub-solidus P–T conditions deduced for the cratonicperidotites. KEY WORDS: asthenosphere diapirs; cratonic lithosphere; deep upper mantle; majoritic garnet     

Vein Metasomatism in Peridotite at Kalskaret near Tafjord, South Norway

Enstatite, anthophyllite, tremolite, and chlorite are developedin a zoned sequence as a vein cross cutting a peridotite bodylocated within the basal gneiss region of southern Norway. Theyare believed to have formed during the main regional metamorphicevent at temperatures around 700 °C and P_total in excessof 6 kb. It is thought that metasomatic reaction occurred by means of(and to a lesser extent directly involved) a pore fluid phaserich in alkali halides. The zonal sequence now found representsthe results of incomplete reaction of the peridotite body withpore fluids derived from the acid gneiss country rocks. Eachzone illustrates partial attainment of equilibrium one componentat a time. Local equilibrium was maintained between the fluidphase and the various silicates during reaction. Questions ofcomponent ‘mobility’ are considered. There appears to be no doubt that enstatite developed by metasomaticreaction on this small scale. This raises interesting possibilitiesof metasomatic development on a larger scale: enstatite occursas a major constituent of some ultrabasic bodies in this regionof southern Norway.