16 research outputs found
Anomalously old biotite <sup>40</sup>Ar/<sup>39</sup>Ar ages in the NW Himalaya
Biotite 40Ar/39Ar ages older than corresponding muscovite 40Ar/39Ar ages, contrary to the diffusion properties of these minerals, are common in the Himalaya and other metamorphic regions. In these cases, biotite 40Ar/39Ar ages are commonly dismissed as âtoo oldâ on account of âexcess Ar.â We present 32 step-heating 40Ar/39Ar ages from 17 samples from central Himachal Pradesh Himalaya, India. In almost all cases, the biotite ages are older than predicted from cooling histories. We document host-rock lithology and chemical composition, mica microstructures, biotite chemical composition, and chlorite and muscovite components of biotite separates to demonstrate that these factors do not offer an explanation for the anomalously old biotite 40Ar/39Ar ages. We discuss possible mechanisms that may account for extraneous Ar (inherited or excess Ar) in these samples. The most likely cause for âtoo-oldâ biotite is excess Ar, i.e., 40Ar that is separated from its parent K. We suggest that this contamination resulted from one or several of the following mechanisms: (1) 40Ar was released during Cenozoic prograde metamorphism; (2) 40Ar transport was restricted due to a temporarily dry intergranular medium; (3) 40Ar was released from melt into a hydrous fluid phase during melt crystallization. Samples from the Main Central Thrust shear zone may be affected by a different mechanism of excess-Ar accumulation, possibly linked to later-stage fluid circulation within the shear zone and chloritization. Different Ar diffusivities and/or solubilities in biotite and muscovite may explain why biotite is more commonly affected by excess Ar than muscovite
Torn Between Two Plates: Exhumation of the Cer Massif (Internal Dinarides) as a FarâField Effect of Carpathian Slab Rollback Inferred From 40 Ar/ 39 Ar Dating and Cross Section Balancing
Abstract Extension across the southern Pannonian Basin and the internal Dinarides is characterized by OligoâMiocene metamorphic core complexes (MCCs) exhumed along mylonitic lowâangle extensional shear zones. Cer MCC at the transition between Dinarides and Pannonian Basin occupies a structural position within the distalâmost Adriatic thrust sheet and originates from two different tectonic processes: Late CretaceousâPaleogene nappeâstacking during a continentâcontinent collision with Adria in a lower plate position, and exhumation related to Miocene extension driven by the Carpathian slabârollback. Structural data and a balanced cross section across the Cer massif show linking of the exhuming shear zone to a breakaway fault, which reactivated the early Late Cretaceous most internal nappe contact. Paleozoic greenschistâto amphiboliteâgrade lithologies surround a polyphase intrusion composed of Iâ and Sâtype granites and were exhumed along a shear zone characterized by topâN transport. Thermobarometric analyses indicate an intrusion depth of 7â8 km of the Oligocene Iâtype granite; cooling below âŒ500°C occurred at 25.4 ± 0.6 Ma (1Ï) yielded by 40 Ar/ 39 Ar dating of hornblende. Biotite and white mica from this intrusion as well as from the mylonitic shear zone yield 40 Ar/ 39 Ar cooling ages of 17â18 Ma independent of the used techniques (in situ laser ablation, singleâgrain total fusion, singleâgrain step heating, and multiâgrain step heating). White mica from the Sâtype granite yield an 40 Ar/ 39 Ar cooling age of 16.7 ± 0.1 Ma (1Ï). Associated dikes intruding the shear zone were also affected by NâS extension resulting in the exhumation of the MCC, which was triggered by the opening of the Pannonian backâarc basin in response to the Carpathian slabârollback.Plain Language Summary Horizontal stretching of continental plates induces thinning of the crustal upper part, melting of rocks, the sinking of the land surface, and formation of large basins. One of the world's bestâstudied basins formed by such a process is the Central European Pannonian Basin. This basin is surrounded by the mountain belts of the Alps, Carpathians, and Dinarides. We have studied rocks between the Pannonian Basin and the southerly adjacent Dinaride Mountains, where rocks deposited in the basin are found right next to rocks that were initially about 7â8 km deep in the crust. These rocks are separated by a shear zone, along which they were brought to the surface. We have dated the activity of the shear zone by measuring concentrations of radioactive isotopes and their decay products contained in deformed minerals. The shear zone was active at a time when the Pannonian Basin started to open due to tectonic processes further NE underneath the Carpathian mountain chain. We also found evidence that the shear zone, which brought metamorphic rocks upwards was formerly one that brought rocks downwards into the crust during an earlier phase of mountain building, predating basin formation.Key Points Activity along the shear zone exhuming Cer metamorphic core complex in the internal Dinarides was dated by 40 Ar/ 39 Ar geochronology to âŒ17 Ma Exhumation was facilitated by extensional reactivation of Late CretaceousâPaleogene nappe contacts resulting from AdriaâEurope collision Extensional reactivation of the thrusts is interpreted as a farâfield effect of OligoâMiocene Carpathian slab rollbac
Torn Between Two Plates: Exhumation of the Cer Massif (Internal Dinarides) as a FarâField Effect of Carpathian Slab Rollback Inferred From 40Ar/39Ar Dating and Cross Section Balancing
Extension across the southern Pannonian Basin and the internal Dinarides is characterized by OligoâMiocene metamorphic core complexes (MCCs) exhumed along mylonitic lowâangle extensional shear zones. Cer MCC at the transition between Dinarides and Pannonian Basin occupies a structural position within the distalâmost Adriatic thrust sheet and originates from two different tectonic processes: Late CretaceousâPaleogene nappeâstacking during a continentâcontinent collision with Adria in a lower plate position, and exhumation related to Miocene extension driven by the Carpathian slabârollback. Structural data and a balanced cross section across the Cer massif show linking of the exhuming shear zone to a breakaway fault, which reactivated the early Late Cretaceous most internal nappe contact. Paleozoic greenschistâto amphiboliteâgrade lithologies surround a polyphase intrusion composed of Iâ and Sâtype granites and were exhumed along a shear zone characterized by topâN transport. Thermobarometric analyses indicate an intrusion depth of 7â8 km of the Oligocene Iâtype granite; cooling below âŒ500°C occurred at 25.4 ± 0.6 Ma (1Ï) yielded by 40Ar/39Ar dating of hornblende. Biotite and white mica from this intrusion as well as from the mylonitic shear zone yield 40Ar/39Ar cooling ages of 17â18 Ma independent of the used techniques (in situ laser ablation, singleâgrain total fusion, singleâgrain step heating, and multiâgrain step heating). White mica from the Sâtype granite yield an 40Ar/39Ar cooling age of 16.7 ± 0.1 Ma (1Ï). Associated dikes intruding the shear zone were also affected by NâS extension resulting in the exhumation of the MCC, which was triggered by the opening of the Pannonian backâarc basin in response to the Carpathian slabârollback.Plain Language Summary:
Horizontal stretching of continental plates induces thinning of the crustal upper part, melting of rocks, the sinking of the land surface, and formation of large basins. One of the world's bestâstudied basins formed by such a process is the Central European Pannonian Basin. This basin is surrounded by the mountain belts of the Alps, Carpathians, and Dinarides. We have studied rocks between the Pannonian Basin and the southerly adjacent Dinaride Mountains, where rocks deposited in the basin are found right next to rocks that were initially about 7â8Â km deep in the crust. These rocks are separated by a shear zone, along which they were brought to the surface. We have dated the activity of the shear zone by measuring concentrations of radioactive isotopes and their decay products contained in deformed minerals. The shear zone was active at a time when the Pannonian Basin started to open due to tectonic processes further NE underneath the Carpathian mountain chain. We also found evidence that the shear zone, which brought metamorphic rocks upwards was formerly one that brought rocks downwards into the crust during an earlier phase of mountain building, predating basin formation.Key Points:
Activity along the shear zone exhuming Cer metamorphic core complex in the internal Dinarides was dated by 40Ar/39Ar geochronology to âŒ17 Ma.
Exhumation was facilitated by extensional reactivation of Late CretaceousâPaleogene nappe contacts resulting from AdriaâEurope collision.
Extensional reactivation of the thrusts is interpreted as a farâfield effect of OligoâMiocene Carpathian slab rollback
Recurrent Local Melting of Metasomatised Lithospheric Mantle in Response to Continental Rifting: Constraints from Basanites and Nephelinites/Melilitites from SE Germany
Cenozoic primitive basanites, nephelinites and melilitites from the Heldburg region, SE Germany, are high-MgO magmas (8.5-14.1 wt % MgO), with low SiO2 (34.2-47.1 wt %) and low to moderately high Al2O3 (9.0-15.5 wt %) and CaO (8.7-12.7 wt %). The Ni and Cr contents of most samples are up to 470 ppm and 640 ppm, respectively, and match those inferred for primary melts. In multi-element diagrams, all samples are highly enriched in incompatible trace elements with chondrite-normalised La/Yb = 19-45, strongly depleted in Rb and K, with primitive mantle normalised K/La = 0.15-0.72, and moderately depleted in Pb. The initial Sr-Nd-Hf isotope compositions (Sr-87/Sr-86 = 0.7033-0.7051, Nd-143/Nd-144 = 0.51279-0.51288 and Hf-176/Hf-177 = 0.28284-0.28294) fall within the range observed for other Tertiary volcanic rocks of the Central European Volcanic Province, whereas Pb-208/Pb-204 and Pb-206/Pb-204 (38.42-38.88 and 18.49-18.98) are distinctly lower at comparable Pb-207/Pb-204 (15.60-15.65). Trace element modelling and pressure-temperature estimates based on major element compositions and experimental data suggest that the nephelinites/melilitites formed within the lowermost lithospheric mantle, close to the lithosphere-asthenosphere boundary, by similar to 3-5% partial melting of a highly enriched, metasomatised, carbonated phlogopite-bearing garnet-lherzolite at temperatures 4 GPa infiltrated the thermal boundary layer at the base of the lithospheric mantle and imprinted a crustal lead isotope, and to a minor extent crustal Sr, Nd and Hf isotope signatures. They also reduced Nb/U, Ce/Pb, Lu/Hf, Sm/Nd, U/Pb and Th/Pb, but increased Rb/Sr and Nb/Ta and amplified the enrichment of LILE and LREE relative to HREE. This lead to the highly-enriched trace element patterns observed in both sample suites, and to overall less radiogenic Pb-206/Pb-204 and 208Pb/204Pb compared to other continental basalts in Central Europe, and to less radiogenic Hf-176/Hf-177 and Nd-143/Nd-144 that plot distinctly below the terrestrial mantle array. Temporal evolution of magmatism in the Heldburg region coincides with the changing Tertiary intraplate stress field in Central Europe, which developed in response to the Alpine orogeny. Magmatism was most probably caused in response to lithosphere deformation and perturbation of the thermal boundary layer, and not by actively upwelling asthenosphere
Age and petrogenesis of Ni-Cu-(PGE) sulfide-bearing gabbroic intrusions in the Lausitz Block, northern Bohemian Massif (Germany/Czech Republic)
The Lausitz Block, located in the northernmost part of the Bohemian Massif, hosts a large number of dike- to stock-shaped gabbroic intrusions that mainly comprise brown hornblende-poor (Group I; i.e. olivine gabbronorite, olivine gabbro, gabbro and diorite) and subordinately brown hornblende-rich lithologies (Group II; i.e. olivine-hornblende gabbro and hornblende gabbro). Several of these intrusions host small-scaled magmatic Ni-Cu-(PGE) sulfide accumulations. The intrusions are part of an interconnected maficâ(ultramafic) plumbing system that intruded Cadomian granodiorites of Lausitz Block in the Middle to Late Devonian during the early stages of the Variscan Orogeny. The previously inferred Devonian age of the intrusions is refined by biotite Ar-Ar dating that yield ages between 372.2 ± 3.7 Ma and 389.1 ± 3.9 Ma (2Ï). Group I and Group II lithologies differ in their mineralogical and geochemical composition. Compared to the Group I lithologies those of Group II are characterized by higher modal contents of primary brown hornblende, Fe-Ti oxides and apatite, by Ti- and Al-enriched clinopyroxene and by lower contents of SiO 2 and increased contents of TiO 2 , P 2 O 5 , LILE, HFSE and LREE. The differences suggest at least two different magmatic series where Group I rocks are linked to tholeiitic basaltic magmas with low to moderate Ti and volatile contents, whereas Group II rocks are derived from Ti- and volatile-enriched moderate-alkaline basaltic magmas. The magmas experienced clinopyroxene fractionation during their crustal ascent and storage, but were only minor affected by crustal contamination (< 5 %) according to Sr-Nd-Pb isotope systematics. Clinopyroxene and whole-rock trace element compositions suggest that primary magmas of both series are linked to an intraplate setting. REE systematics suggest primary magma contributions from both garnet and spinel peridotite sources. Group II samples bear evidence for higher proportions of garnet peridotite-derived melts, and trace element modelling indicates melting degrees between ~5â20 % for both groups. The proposed intraplate magmatism is might been related to a subduction slab retreat within the framework of the Variscan orogeny, which leads to lithosphere extension and enhanced decompression melting of the mantle beneath the Lausitz Block. Cu/Zr ratios < 1 of gabbroic rocks from several intrusions suggest a previous segregation of magmatic sulfides in other sections of the magmatic plumbing system and give rise for a vertical and lateral Ni-Cu exploration potential
The Pieniny Klippen Belt in the Western Carpathians of northeastern Slovakia : structural evidence for transpression
Abstract
The Pieniny Klippen Belt represents a 600-km-long but only a few kilometers wide suture zone in the Carpathian orogenic belt. Based on a quantitative analysis along a part of its NW-trending segment in northeastern Slovakia, we present structural data supporting transpression, the continuous interaction of strike-slip shearing, horizontal shortening, and vertical lengthening, as a major deformation style in its polyphase deformation history. Dextral transpression is expressed in the map scale and outcrop fault pattern, the oblique orientation of fold axes to the faults bounding the Klippen Belt, and extension parallel to the fold axes. The transpression-related strain field is described and quantified by the analysis of: (1) orientation of rotated fold axes (displaying an acute angle to the margins of the Klippen Belt); (2) orientation and geometry of paleostress derived from mesoscale fault-striae analysis (E-trend of Ï3-trajectories and flattening geometry); and (3) the deformation history indicated by extension veins (non-coaxial regime). Different techniques using fault-striae data quantify paleostress and subdivide heterogeneous data sets mathematically into homogeneous subsets. The observed deformation history is modelled as a homogeneous transpression deformation. The best-fitting model requires a NW-trending (present-day orientation) external contraction direction (e.g., plate-slip vector), and predicts 16% fold axes parallel extension and 23% axial plane normal shortening
40Ar/39Ar ages and bulk-rock chemistry of the lower submarine units of the central and western Aleutian Arc
Highlights
âą The revised minimum subduction initiation age for the Aleutian system is 48âŻMa.
âą The evolution of the arc was characterized by three distinct magmatic pulses.
âą The types of magmas erupted appear to have changed during the arc evolution.
In order to further constrain the timing of the Aleutian Arc initiation as well as its early evolution, an extensive 40Ar/39Ar dating and geochemical (major and selected trace elements) campaign (40 samples) of the lower units of the Aleutian ridge has been carried out on samples dredged from deep fore-arc canyons and rear arc tectonic structures. The new dataset slightly increases the minimum inception age for the Aleutian system, with the two oldest samples dated at 46.1âŻÂ±âŻ3.3âŻMa and 47.80âŻÂ±âŻ0.57âŻMa. Both mid Eocene ages were obtained on tholeiitic mafic volcanic rocks from the western section of the arc. The new data also support the occurrence of three distinct periods of enhanced magmatic activity (magmatic pulses) during the pre-Quaternary evolution of the arc (at 38â27, 16â11 and 6â0âŻMa), as previously suggested based on a more limited and dominantly subaerial dataset. Moreover, the data refine the duration of the first pulse of activity, which ended 2âŻMa later than previous estimates. The first and last pulses may be associated with rotations of the subducting plates while the second pulse might result from regional tectonic changes. The significant overlap between the age distribution of the submarine and subaerial samples suggests that much of the earlier parts of the arc may have been uplifted and subaerially exposed. The expected crustal growth associated with the pulses is unlikely to have significantly impacted magmatic residence times, since no variation in the degree of differentiation of the rocks can be observed during or after the pulses. On the other hand, the type of magmas erupted may have changed during the arc evolution. Prior to the first pulse, activity appears to have been dominantly tholeiitic. On the other hand, the first pulse was characterized by coeval tholeiitic, transitional and calc-alkaline magmas, with calc-alkaline activity increasing after the first ~3âŻMa. Subsequently, a dominantly calc-alkaline period occurred from 29 to 8âŻMa, followed by a progressive return of coeval tholeiitic, transitional and calc-alkaline activity. These temporal changes in magma types correspond to likely variations in arc crustal thickness beneath the active front, and could therefore be a response to physical changes of the overriding plate