İstván Dunkl scite author profile

The structure of the Pannonian basin is the result of distinct modes of Mid-Late Miocene extension exerting a profound effect on the lithospheric configuration, which continues even today. As the first manifestation of extensional collapse, large magnitude, metamorphic core complex style extension took place at the beginning of the Mid-Miocene in certain parts of the basin. Extrapolation of the present-day high heat flow in the basin, corrected for the blanketing effect of the basin fill, indicates a hot and thin lithosphere at the onset of extension. This initial condition, combined with the relatively thick crust inherited from earlier Alpine compressional episodes, appears to be responsible for the core complex type extension at the beginning of the syn-rift period. This type of extension is well documented in the northwestern Pannonian basin. Newly obtained deep reflection seismic and fission-track data integrated with well data from the southeastern part of the basin suggests that it developed in a similar fashion. Shortly after the initial period, the style of syn-rift extension changed to a wide-rift style, covering an area of much larger geographic extent. The associated normal faults revealed by industry reflection seismic data tend to dominate within the upper crust, obscuring pre-existing structures. However, several deep seismic profiles, constrained by gravity and geothermal modeling, image the entire lithosphere beneath the basin. It is the Mid-Miocene synrift extension which is still reflected in the structure of the Pannonian lithosphere, on the scale of the whole basin system. The gradually diminishing extension during the Late Miocene/Pliocene could not advance to the localization of extension into narrow rift zones in the Pannonian region, except some deep subbasins such as the Makó/Békés and Danube basins. These basins are underlain coincidently by anomalously thin crust (22–25 km) and lithosphere (45–60 km). Significant departures (up to 130 mW m −2 ) from the average present-day surface heat flow ( c. 90 mW m −2 ) and intensive Pliocene alkaline magmatism are also regarded as evidence for the initiation of two newly defined narrow rift zones (Tisza and Duna) in the Pannonian basin system. However, both of these narrow rifts failed since the final docking of the Eastern Carpathians onto the European foreland excluded any further extension of the back-arc region.

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The giant Shakhdara migmatitic gneiss dome, Pamir, India‐Asia collision zone: 2. Timing of dome formation

Stübner

et al. 2013

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[1] Cenozoic gneiss domes-exposing middle-lower crustal rocks-cover~30% of the surface exposure of the Pamir, western India-Asia collision zone; they allow an unparalleled view into the deep crust of the Asian plate. We use titanite, monazite, and zircon U/Th-Pb, mica Ar/ 39 Ar, zircon and apatite fission track, and zircon (U-Th)/He ages to constrain the exhumation history of the~350 × 90 km Shakhdara-Alichur dome, southwestern Pamir. Doming started at 21-20 Ma along the Gunt top-to-N normal-shear zone of the northern Shakhdara dome. The bulk of the exhumation occurred by~NNW-ward extrusion of the footwall of the crustal-scale South Pamir normal-shear zone along the southern Shakhdara dome boundary. Footwall extrusion was active from~18-15 Ma to~2 Ma at~10 mm/yr slip and with vertical exhumation rates of 1-3 mm/yr; it resulted in up to 90 km~N-S extension, coeval with~N-S convergence between India and Asia. Erosion rates were 0.3-0.5 mm/yr within the domes and 0.1-0.3 mm/yr in the horst separating the Shakhdara and Alichur domes and in the southeastern Pamir plateau; rates were highest along the dome axis in the southern part of the Shakhdara dome. Incision along the major drainages was up to 1.0 mm/yr. Thermal modeling suggests geothermal gradients as high as 60°C/km along the trace of the South Pamir shear zone and their strong N-S variation across the dome; the gradients relaxed to ≤40-45°C/km since the end of doming.

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Trackkey: a Windows program for calculation and graphical presentation of fission track data

Dunkl

2002

Computers & Geosciences

313

177

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Individual dating of detrital apatite and zircon crystals in arenitic sediments by the fission track method is a useful, promising technique for provenance analysis. The ages form clusters which are characteristic for the main source areas of siliciclastic sediments. The identification of age groups and the comparison of ''age patterns'' of sedimentary samples require graphical presentation of the data sets. A Visual Basic program is presented for calculating the main statistical values and plotting the single grain ages. TRACKKEY provides a complete system for data processing for the external detector method using both zeta and activation calibration systems. The plots are linked to each other and they are presented in one window for better overview. The program allows fast and easy selection and grouping of individual data. #

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İstván Dunkl

Palinspastic reconstruction and topographic evolution of the Eastern Alps during late Tertiary tectonic extrusion

Post-collisional orogen-parallel large-scale extension in the Eastern Alps

Lithospheric structure of the Pannonian basin derived from seismic, gravity and geothermal data

The giant Shakhdara migmatitic gneiss dome, Pamir, India‐Asia collision zone: 2. Timing of dome formation

Trackkey: a Windows program for calculation and graphical presentation of fission track data

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