DOCSLIB.ORG

Coupling Between Climate and Tectonics? : Low Temperature

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Coupling Between Climate and Tectonics? : Low Temperature STR12/14 Christoph von Hagke Coupling between Climate and Tectonics? Low temperature thermochronology and structural geology applied to the pro‐wedge of the European Alps Scientific Technical Report STR12/14 ISSN 1610-0956 and Tectonics? Climate between Coupling Hagke, C. v. www.gfz-potsdam.de Christoph von Hagke Coupling between Climate and Tectonics? Low temperature thermochronology and structural geology applied to the pro‐wedge of the European Alps Dissertation zur Erlangung des Doktorgrades im Fachbereich Geowissenschaften an der Freien Universität Berlin Berlin, 2012 Imprint Helmholtz Centre Potsdam GFZ German Research Centre for Geosciences Telegrafenberg D-14473 Potsdam Printed in Potsdam, Germany October 2012 ISSN 1610-0956 DOI: 10.2312/GFZ.b103-12148 Scientific Technical Report STR12/14 URN: urn:nbn:de:kobv:b103-12148 This work is published in the GFZ series Scientific Technical Report (STR) and electronically available at GFZ website www.gfz-potsdam.de > News > GFZ Publications Coupling between Climate and Tectonics? Low temperature thermochronology and structural geology applied to the pro‐wedge of the European Alps Dissertation zur Erlangung des Doktorgrades im Fachbereich Geowissenschaften an der Freien Universität Berlin Christoph von Hagke Berlin, 2012 1. Gutachter: Prof. Dr. Onno Oncken Freie Universität Berlin Helmholtz‐Zentrum Potsdam Deutsches GeoForschungsZentrum GFZ 2. Gutachter: Prof. Dr. Mark Handy Freie Universität Berlin Tag der Disputation: 27.06.2012 Scientific Technical Report STR 12/14 Deutsches GeoForschungsZentrum GFZ DOI: 10.2312/GFZ.b103-12148 Erklärung Hiermit versichere ich, dass die vorliegende Dissertation ohne unzulässige Hilfe Dritter und ohne Benutzung anderer als der angegebenen Literatur angefertigt wurde. Die Stellen der Arbeit, die anderen Werken wörtlich oder inhaltlich entnommen sind, wurden durch entsprechende Angaben der Quellen kenntlich gemacht. Diese Arbeit hat in gleicher oder ähnlicher Form noch keiner Prüfungsbehörde vorgelegen. Berlin, Mai 2012 Scientific Technical Report STR 12/14 Deutsches GeoForschungsZentrum GFZ DOI: 10.2312/GFZ.b103-12148 HARNISCHSTRIEMEN, Faltenachsen, Durchstich‐ punkte: dein Gelände. An beiden Polen der Kluftrose, lesbar: dein geächtetes Wort. Nordwahr. Südhell. SLICKENSIDES, fold‐axes, rechanneling‐ points: your terrain. On both poles of the cleftrose, legible: your outlawed word. Northtrue. Sunbright. Paul Celan 1967 (Atemwende), translated by Pierre Joris (Breathturn) Scientific Technical Report STR 12/14 Deutsches GeoForschungsZentrum GFZ DOI: 10.2312/GFZ.b103-12148 Table of content Coupling between Climate and Tectonics? ................................................................................ 1 Low temperature thermochronology and structural geology applied to the pro‐wedge of the European Alps ............................................................................................................................ 1 1 Thermochronological approach to the late stage evolution of the Molasse basin and the Interaction between climate and tectonics ............................................................................... 9 1.1 General Introduction and Summary ............................................................................ 9 1.2 Allgemeine Einführung und Zusammenfassung ........................................................ 12 1.3 The Molasse Basin ..................................................................................................... 15 1.3.1 Geographic setting ............................................................................................. 15 1.3.2 Pre‐Tertiary Basin Evolution ............................................................................... 15 1.3.3 Tertiary Basin Evolution ..................................................................................... 17 1.3.4 Tectonic Setting .................................................................................................. 22 1.4 Methods ..................................................................................................................... 23 1.4.1 Principles of Thermochronology ........................................................................ 23 The concept of closure temperature ................................................................................... 23 1.4.2 Fission track formation and fading ..................................................................... 26 1.4.3 Fission track age determination ......................................................................... 29 1.4.4 (U‐Th‐Sm)/He dating .......................................................................................... 31 2 Resolving the latest uplift and erosion history of the Northern Alpine Foreland Basin with low temperature thermochronology ............................................................................... 35 2.1 Introduction ............................................................................................................... 35 2.2 Regional geologic context .......................................................................................... 37 Tertiary basin evolution ....................................................................................................... 38 2.3 The Subalpine Molasse .............................................................................................. 39 General overview of the discussed cross sections ............................................................... 41 2.4 Fission Track and (U‐Th‐Sm)/He Principles and Methods ......................................... 42 Scientific Technical Report STR 12/14 Deutsches GeoForschungsZentrum GFZ DOI: 10.2312/GFZ.b103-12148 2.5 Sampling Strategy ...................................................................................................... 43 2.6 Thermal Modelling of the data .................................................................................. 45 2.7 Results ........................................................................................................................ 46 2.7.1 AFT age distribution ........................................................................................... 46 Entlebuch horizontal section ................................................................................................ 46 Entlebuch vertical section .................................................................................................... 55 Rigi horizontal section .......................................................................................................... 56 Rigi vertical section .............................................................................................................. 58 2.7.2 Comparison of EDM and LA‐ICP‐MS AFT results ................................................ 59 2.7.3 (U‐Th‐Sm)/He age distribution ........................................................................... 61 Entlebuch horizontal section ................................................................................................ 61 Entlebuch drill hole section .................................................................................................. 61 Rigi horizontal section .......................................................................................................... 62 Rigi vertical section .............................................................................................................. 63 2.7.4 Comparison of apatite (U‐Th‐Sm)/He and AFT results ...................................... 63 2.7.5 Modelled burial and exhumation histories ........................................................ 64 2.8 Discussion .................................................................................................................. 69 2.8.1 Thermochronology age pattern across thrusts .................................................. 70 2.8.2 Heat flow across active thrusts .......................................................................... 72 2.8.3 Tectonics in the Subalpine Molasse ................................................................... 72 2.8.4 The link to the inner Alps ................................................................................... 73 2.8.5 The link to the Jura Mountains and critical taper theory .................................. 75 2.9 Conclusions ................................................................................................................ 76 2.10 Acknowledgements ................................................................................................... 77 3 Supplementary information to “Resolving the latest uplift and erosion history of the Northern Alpine Foreland Basin with low temperature thermochronology” ......................... 78 Scientific Technical Report STR 12/14 Deutsches GeoForschungsZentrum GFZ DOI: 10.2312/GFZ.b103-12148 3.1 Density and magnetic separation techniques applied .............................................. 78 3.2 Apatite fission track dating and its application ......................................................... 78 3.2.1 Theoretical background ..................................................................................... 78 3.2.2 Application of the fission track method ............................................................. 79 3.3 Assumption of Ns = 0.5 .............................................................................................. 89 3.4 EDM sampling strategy and age dating
Load more

Recommended publications
  • The Structure of the Alps: an Overview 1 Institut Fiir Geologie Und Paläontologie, Hellbrunnerstr. 34, A-5020 Salzburg, Austria
    Carpathian-Balkan Geological pp. 7-24 Salzburg Association, XVI Con ress Wien, 1998 The structure of the Alps: an overview F. Neubauer Genser Handler and W. Kurz \ J. 1, R. 1 2 1 Institut fiir Geologie und Paläontologie, Hellbrunnerstr. 34, A-5020 Salzburg, Austria. 2 Institut fiir Geologie und Paläontologie, Heinrichstr. 26, A-80 10 Graz, Austria Abstract New data on the present structure and the Late Paleozoic to Recent geological evolution ofthe Eastem Alps are reviewed mainly in respect to the distribution of Alpidic, Cretaceous and Tertiary, metamorphic overprints and the corresponding structure. Following these data, the Alps as a whole, and the Eastem Alps in particular, are the result of two independent Alpidic collisional orogens: The Cretaceous orogeny fo rmed the present Austroalpine units sensu lato (including from fo otwall to hangingwall the Austroalpine s. str. unit, the Meliata-Hallstatt units, and the Upper Juvavic units), the Eocene-Oligocene orogeny resulted from continent­ continent collision and overriding of the stable European continental lithosphere by the Austroalpine continental microplate. Consequently, a fundamental difference in present-day structure of the Eastem and Centrai/Westem Alps resulted. Exhumation of metamorphic crust fo rmed during Cretaceous and Tertiary orogenies resulted from several processes including subvertical extrusion due to lithospheric indentation, tectonic unroofing and erosional denudation. Original paleogeographic relationships were destroyed and veiled by late Cretaceous sinistral shear, and Oligocene-Miocene sinistral wrenching within Austroalpine units, and subsequent eastward lateral escape of units exposed within the centrat axis of the Alps along the Periadriatic fault system due to the indentation ofthe rigid Southalpine indenter.
    [Show full text]
  • The Eastern Alps: Result of a Two-Stage Collision Process
    © Österreichische Geologische Gesellschaft/Austria; download unter www.geol-ges.at/ und www.biologiezentrum.at Mil. Cteto-r. Goo GOG. ISSN 02hl 7-193 92 11999; 117 13-1 Wen Jui 2000 The Eastern Alps: Result of a two-stage collision process FRANZ NEUBAUER1, JOHANN GENSER1, ROBERT HANDLER1 8 Figures Abstract The present structure and the Late Paleozoic to Recent geological evolution of the Alps are reviewed mainly with respect to the distribution of Alpidic, metamorphic overprints of Cretaceous and Tertiary age and the corresponding ductile structure. According to these data, the Alps as a whole, and the Eastern Alps in particular, are the result of two independent Alpidic collisional orogenies: The Cretaceous orogeny formed the present Austroaipine units sensu lato (extending from bottom to top of the Austroaipine unit s. str., the Meliata unit, and the Upper Juvavic unit) including a very low- to eclogite-grade metamorphic overprint. The Eocene-Oligocene orogeny resulted from an oblique continent-continent collision and overriding of the stable European continental lithosphere by the combined Austroalpine/Adriatic continental microplate. A fundamental difference seen in the present-day structure of the Eastern and Central/ Western Alps resulted as the Austroaipine units with a pronounced remnants of a Oligocene/Neogene relief are mainly exposed in the Eastern Alps, in contrast to the Central/Western Alps with Penninic units, which have been metamorphosed during Oligocene. Exhumation of metamorphic crust, formed during Cretaceous and Tertiary orogenies, arose from several processes including subvertical extrusion due to lithospheric indentation, tectonic unroofing and erosional denudation. Original paleogeographic relationships were destroyed and veiled by late Cretaceous sinistral shear, Oligocene-Miocene sinistral wrenching along ENE-trending faults within eastern Austroaipine units and the subsequent eastward lateral escape of units exposed within the central axis of the Alps.
    [Show full text]
  • Field Trip - Alps 2013
    Student paper Field trip - Alps 2013 Evolution of the Penninic nappes - geometry & P-T-t history Kevin Urhahn Abstract Continental collision during alpine orogeny entailed a thrust and fold belt system. The Penninic nappes are one of the major thrust sheet systems in the internal Alps. Extensive seismic researches (NFP20,...) and geological windows (Tauern-window, Engadin-window, Rechnitz-window), as well as a range of outcrops lead to an improved understanding about the nappe architecture of the Penninic system. This paper deals with the shape, structure and composition of the Penninic nappes. Furthermore, the P-T-t history1 of the Penninic nappes during the alpine orogeny, from the Cretaceous until the Oligocene, will be discussed. 1 The P-T-t history of the Penninic nappes is not completely covered in this paper. The second part, of the last evolution of the Alpine orogeny, from Oligocene until today is covered by Daniel Finken. 1. Introduction The Penninic can be subdivided into three partitions which are distinguishable by their depositional environment (PFIFFNER 2010). The depositional environments are situated between the continental margin of Europe and the Adriatic continent (MAXELON et al. 2005). The Sediments of the Valais-trough (mostly Bündnerschists) where deposited onto a thin continental crust and are summarized to the Lower Penninic nappes (PFIFFNER 2010). The Middle Penninic nappes are comprised of sediments of the Briançon-micro-continent. The rock compositions of the Lower- (Simano-, Adula- and Antigori-nappe) and Middle- Penninic nappes (Klippen-nappe) encompass Mesozoic to Cenozoic sediments, which are sheared off from their crystalline basement. Additionally crystalline basement form separate nappe stacks (PFIFFNER 2010).
    [Show full text]
  • Engadin Window) Near Ischgl/Tyrol
    MITT. ÖSTERR. MINER. GES. 163 (2017) WALKING ON JURASSIC OCEAN FLOOR AT THE IDALPE (ENGADIN WINDOW) NEAR ISCHGL/TYROL Karl Krainer1 & Peter Tropper2 1Institute of Geology, University of Innsbruck, Innrain 52f, A-6020 Innsbruck 2Institute of Mineralogy and Petrography, University of Innsbruck, Innrain 52f, A-6020 Innsbruck Introduction In the Lower Engadine Window rocks of the Penninic Unit are exposed which originally were formed in the Piemont-Ligurian Ocean, the Iberian-Brianconnais microcontinent and the Valais Ocean. The Penninic rocks of the Lower Engadi- ne Window are overlain by Austrolpine nappes: the Silvretta Metamorphic Com- plex (Silvretta-Seckau Nappe System sensu SCHmiD et al. 2004) in the north, the Stubai-Ötztal Metamorphic Complex (Ötztal-Bundschuh Nappe System sensu SCHmiD et al. 2004) in the southeast and east, and the Engadine Dolomites. The Penninic rocks of the Lower Engadine Window are characterized by a com- plex tectonic structure and can be divided into three nappe systems (SCHmiD et al., 2004; GRubeR et al., 2010; see also Tollmann, 1977; ObeRHauseR, 1980): a.) Lower Penninic Nappes including rocks of the former Valais Ocean (Cre- taceous – Paleogene) b.) Middle Penninic Nappes composed of rocks of the Iberia-Brianconnais microcontinent, and c.) Upper Penninic Nappe, composed of rocks oft he former Piemont-Ligu- rian Ocean. Lower Penninic Nappes include the Zone of Pfunds and Zone of Roz – Cham- patsch – Pezid. The dominant rocks are different types of calcareous mica schists and „Bündnerschiefer“. Locally fragments of the oceanic crust and upper mantle (ophiolites) are intecalated. The Middle Penninic Nappes include the Fimber-Zone and Zone of Prutz – Ramosch.
    [Show full text]
  • Map-Band 149 Kopie
    MITT.ÖSTERR.MINER.GES. 149 (2004) EXPLANATORY NOTES TO THE MAP: METAMORPHIC STRUCTURE OF THE ALPS AGE MAP OF THE METAMORPHIC STRUCTURE OF THE ALPS – TECTONIC INTERPRETATION AND OUTSTANDING PROBLEMS by M. R. Handy1 & R. Oberhänsli2 1Institut für Geologische Wissenschaften Freie Universität Berlin, Malteserstrasse 74-100, 12249 Berlin, Germany 2Institut für Geowissenschaften Universität Potsdam, Karl-Liebknecht-Str. 25, 14476 Potsdam-Golm, Germany Abstract The mapped distribution of post-Jurassic mineral isotopic ages in the Alps reveals two meta- morphic cycles, each consisting of a pressure-dominated stage and a subsequent temperature- dominated stage: (1) a Late Cretaceous cycle in the Eastern Alps, indicated on the map by purple dots and green colours; and (2) a Late Cretaceous to Early- to Mid-Tertiary cycle in the Western and Central Alps, Corsica and the Tauern window, marked on the map with blue and red dots and yellow and orange colours. The first cycle is attributed to the subduction of part of the Austroalpine passive margin follo- wing Jurassic closure of the Middle Triassic, Meliata-Hallstatt ocean basin. This involved nap- pe stacking, extensional exhumation and cooling. The second cycle is related to the subduction of the Jurassic-Cretaceous, Liguro-Piemont and Valais ocean basins as well as distal parts of the European and Apulian continental margins. Sub- sequent exhumation and cooling of the Tertiary nappe pile occurred during oblique indentation of Europe by the Apulian margin in Oligo-Miocene time. Despite a wealth of geochronologic work in the Alps, there are still large areas where relevant data are lacking or where existing da- ta yield conflicting interpretations.
    [Show full text]
  • Handy Etal 10 ESR.Pdf
    This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research and education use, including for instruction at the authors institution and sharing with colleagues. Other uses, including reproduction and distribution, or selling or licensing copies, or posting to personal, institutional or third party websites are prohibited. In most cases authors are permitted to post their version of the article (e.g. in Word or Tex form) to their personal website or institutional repository. Authors requiring further information regarding Elsevier’s archiving and manuscript policies are encouraged to visit: http://www.elsevier.com/copyright Author's personal copy Earth-Science Reviews 102 (2010) 121–158 Contents lists available at ScienceDirect Earth-Science Reviews journal homepage: www.elsevier.com/locate/earscirev Reconciling plate-tectonic reconstructions of Alpine Tethys with the geological–geophysical record of spreading and subduction in the Alps Mark R. Handy a,⁎, Stefan M. Schmid a,c,1, Romain Bousquet b,2, Eduard Kissling c,3, Daniel Bernoulli d,4 a Institut für Geologische Wissenschaften, Freie Universität Berlin, Malteserstrasse 74-100, D-12249 Berlin, Germany b Institut für Geowissenschaften, Universität Potsdam, Postfach 601553, D-14415 Potsdam, Germany c Institut für Geophysik, ETH-Zentrum, Sonneggstrasse 5, CH-8092 Zurich, Switzerland d Geologisch-Paläontologisches Institut, Universität Basel, Bernoullistrasse 32, CH-4056 Basel, Switzerland article info abstract Article history: A new reconstruction of Alpine Tethys combines plate-kinematic modelling with a wealth of geological data Received 23 November 2008 and seismic tomography to shed light on its evolution, from sea-floor spreading through subduction to Accepted 1 June 2010 collision in the Alps.
    [Show full text]
  • Alpmed 2 Handy Summary Alpscarpathians-Dinarides
    Geodynamics of the Alpine Mediterranean chains Overview of their structure & history Mark. R. Handy Outline • Alps • Carpathians & Pannonian Basin • Dinarides • Northern Apennines • Summary of tectonic history Accreted Adriatic & European units Handy et al., simplified from Schmid et al. 2004, 2008 Carpathians European Alps Plate Adriatic Plate European Plate Dinarides Apennines ? Alps Handy et al., simplified from Schmid et al. 2004, 2008 European Carpathians Plate Alps Adriatic Plate European Plate Dinarides Apennines ? Plate tectonic map of theJurassic-Cretaceous Alps 8 û 10 û 12 û boundarY PALEOGEOGRAPHIC (Neotethys suture) UNITS IN THE ALPS Paleogene -Europe Rhenodanubian flysch modified after Froitzheim et al. ( 1996 ) ) Adria Walsertal zone boundarYNFP-20 EAST suture Z Ÿ rich Glockner nappe window Lower plate (Europe)plate Northern Calcareous Alps Tauern W Š gital flysch Venediger nappe 47 û Schlieren flysch Falknis Sulzfluh Bern dow Matrei zone NPB NPB (Alpine Tethys win Helvetic Nappes Austroalpine Alps Gurnigel flysch Tasna Schams Arosa zone Engadine Ela NFP-20 WEST Aar Gotthard Ortler Adula Platta Suretta Tambo A v Bernina Upper plate (Adria) epontine Geneva Be. Margna Sella Malenco Adamello Breccia Insubric line 46 û nappe ECORS-CROP Southern Alps Antrona Generoso M. Rosa Giudicarie line M. Nudo Dent Blanche - Sesia Insubric line Roignais Versoyen Europe Grand European- margin Paradiso Milano Canavese AdriaValais basin Grenoble Lanzo Oceanic units: boundarYBrian onnais terrane 45 û Torino Present Piemont-Liguria basin Dora Maira plate Relics of Alpine Tethys Margna-Sesia fragment N Apulian margin Froitzheim et al. 1996 100 km Meliata-Hallstatt basin The Alps – the traditional geological-geographical subdivision Eastern Alps Engadin Window Jura Rechnitz Window Central Alps Préalpes Klippe Tauern Window Dente Blanche Klippe Southern Alps Western Alps Handy et al.
    [Show full text]
  • Crustal Structures Beneath the Eastern and Southern Alps from Ambient Noise Tomography Ehsan Qorbani1,2, Dimitri Zigone3, Mark R
    https://doi.org/10.5194/se-2019-177 Preprint. Discussion started: 16 January 2020 c Author(s) 2020. CC BY 4.0 License. Crustal structures beneath the Eastern and Southern Alps from ambient noise tomography Ehsan Qorbani1,2, Dimitri Zigone3, Mark R. Handy4, Götz Bokelmann2, and AlpArray-EASI working group5 1International Data Center, CTBTO, Vienna, Austria 2Department of Meteorology and Geophysics, University of Vienna, Austria 3Institut de Physique du Globe de Strasbourg, EOST, Université de Strasbourg/CNRS, Strasbourg, France 4Institute of Geological Sciences, Freie Universität Berlin, Berlin, Germany 5Eastern Alpine Seismic Investigation (EASI) AlpArray Complimentary Experiment. AlpArray Working Group Correspondence: Ehsan Qorbani ([email protected]) Abstract. We study the crustal structure under the Eastern and Southern Alps using ambient noise tomography. We use cross- correlations of ambient seismic noise between pairs of 71 permanent stations and 19 stations of the EASI profile to derive new high-resolution 3-D shear-velocity models for the crust. Continuous records from 2014 and 2015 are cross-correlated to estimate Green’s functions of Rayleigh and Love waves propagating between the station pairs. Group velocities extracted 5 from the cross-correlations are inverted to obtain isotropic 3-D Rayleigh and Love-wave shear-wave velocity models. Our high resolution models image several velocity anomalies and contrasts and reveal details of the crustal structure. Velocity variations at short periods correlate very closely with the lithologies of tectonic units at the surface and projected to depth. Low-velocity zones, associated with the Po and Molasse sedimentary basins, are imaged well to the south and north of the Alps, respectively.
    [Show full text]
  • Complete Dissertation
    VU Research Portal Extracting Erosion and Exhumation Patterns from Detrital Thermochronology Gemignani, L. 2018 document version Publisher's PDF, also known as Version of record Link to publication in VU Research Portal citation for published version (APA) Gemignani, L. (2018). Extracting Erosion and Exhumation Patterns from Detrital Thermochronology: an example from the eastern Himalaya. General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal ? Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. E-mail address: [email protected] Download date: 08. Oct. 2021 Rivers transport key information that can be used as a proxy to infer the evo- lution of the landscape of eroding mountain ranges. Detrital thermochronology aims at shedding new light about the timing of past tectonic events, fi xing their rates. The Himalaya is a natural laboratory where studying those
    [Show full text]
  • Overview of the Paleogene of the Eastern Alps
    Overview of the Paleogene of the Eastern Alps Walter KuRz1, Harald FR1Tz1, Werner E. P1LLER1 , Franz NEUBAUER2 , Johann GENSER2 KuRz, W., FR1rz, H., P1LLER, W. E., NEUBAUER, F. & GENsER, J., 2001: Overview of the Paleogene of the Eastern Alps. - In: PILLER, W. E. & RASSER, M. W. (Eds.): Paleogene of the Eastern Alps. - Österr. Akad. Wiss., Schriftenr. Erdwiss. Komm. 14: 11-56, 6 Figs., 1 Tab., Wien. Abstract: The evolution of the tectonic units of the Eastern Alps of Austria during the Paleogene is summarized. Based on the structural, petrological, geochronological, and sedimentological-strati­ graphic data, a plate tectonic-geodynamic interpretation of the evolution of the Eastern Alps of Austria during the Paleogene is deduced. The starting-point of this evolution is the consolidation of the Austroalpine nappe complex and subsequent cooling of the Austroalpine unit du ring the Late Cretaceous. During the Late Cretaceous and the Paleogene subduction of the Penninic oceanic domains and the subsequent collision between the Penninic continental and the Austroalpine units is documented. The latter were in an upper plate position. The orogeny during the Paleogene is primarily controlled by subduction, collision and closure of the Penninic oceanic domains. This is indicated by the deposition of turbiditic sediments both on top of the Austroalpine upper nappe complex (Gosau sediment basins), and on the Penninic-European lower plate (Matrei Zone, Kaserer Group?, Rhenodanubian Flysch). Collision is followed by cessation of flysch sedimentation, and the deposition of Molasse sediments, which started in the Late Eocene. Contemporaneously, subduc­ tion and collision is documented by high-pressure metamorphism in the internal zones of the Eastern Alps, which affected the Middle- and Southpenninic units, and by Late Oligocene magma­ tism along the Periadriatic Lineament, which resulted from the break off of the subducted slab of Penninic oceanic lithosphere.
    [Show full text]
  • Exhumation of the Rechnitz Window at the Border of the Eastern Alps and Pannonian Basin During Neogene Extension
    TECTONOPHYSICS ELSEVIER Tectonophysics 272 (1997) 197-211 Exhumation of the Rechnitz Window at the border of the Eastern Alps and Pannonian Basin during Neogene extension IstvS.n Dunkl a,b,*, Attila Dem6ny a a Laboratory for Geochemical Research, Hungarian Academy of Sciences, BudaOrsi tlt 45, H-1112 Budapest, Hungary b lnstitutfiir Geologie und Paliiontologie, Universit?it Tiibingen, Sigwartstrasse 10, D-72076 Tiibingen, Germany Abstract The Rechnitz Window is the easternmost Penninic window of the Alps and the only one that is partly covered by Neogene sediments. Zircon and apatite fission-track ages have been measured on the Penninic metasediments of the Rechnitz series to better understand the exhumation of the window at the Alpine-Pannonian border. The zircon FT ages range from 21.9 to 13.4 Ma, similar to the white mica K/Ar ages (19 and 23 Ma). The exhumation rate during the Early Miocene extension was high (~40°C/Ma). Apatite samples display Fr ages of 7.3 and 9.7 Ma, thus the cooling rate was significantly less (7-11°C/Ma) during the post-rift uplift in Late Miocene-Pliocene than in the Early Miocene escape period. Zircon FT ages decrease eastward due to the gradual southeastward slide of the Austroalpine cover along low-angle normal faults. The exhumation of the Rechnitz metamorphic core complex is younger than the unroofing of the eastern Tauern Window. Morphology of detrital zircon crystals of the Penninic metasediments was used for the differentiation of tectonic subunits and to trace the internal structure of the window. One population was probably derived from undifferentiated calc-alkaline granitoids and tholeiitic granitoid sources, while the other derived from evolved calc-alkaline granitoids and alkaline granitoids of anorogenic complexes.
    [Show full text]
  • Handy10 Plate Reconstr Alpine
    Earth-Science Reviews 102 (2010) 121–158 Contents lists available at ScienceDirect Earth-Science Reviews journal homepage: www.elsevier.com/locate/earscirev Reconciling plate-tectonic reconstructions of Alpine Tethys with the geological–geophysical record of spreading and subduction in the Alps Mark R. Handy a,⁎, Stefan M. Schmid a,c,1, Romain Bousquet b,2, Eduard Kissling c,3, Daniel Bernoulli d,4 a Institut für Geologische Wissenschaften, Freie Universität Berlin, Malteserstrasse 74-100, D-12249 Berlin, Germany b Institut für Geowissenschaften, Universität Potsdam, Postfach 601553, D-14415 Potsdam, Germany c Institut für Geophysik, ETH-Zentrum, Sonneggstrasse 5, CH-8092 Zurich, Switzerland d Geologisch-Paläontologisches Institut, Universität Basel, Bernoullistrasse 32, CH-4056 Basel, Switzerland article info abstract Article history: A new reconstruction of Alpine Tethys combines plate-kinematic modelling with a wealth of geological data Received 23 November 2008 and seismic tomography to shed light on its evolution, from sea-floor spreading through subduction to Accepted 1 June 2010 collision in the Alps. Unlike previous models, which relate the fate of Alpine Tethys solely to relative motions Available online 12 June 2010 of Africa, Iberia and Europe during opening of the Atlantic, our reconstruction additionally invokes independent microplates whose motions are constrained primarily by the geological record. The motions of Keywords: these microplates (Adria, Iberia, Alcapia, Alkapecia, and Tiszia) relative to both Africa and Europe during Late Tethys Alps Cretaceous to Cenozoic time involved the subduction of remnant Tethyan basins during the following three Mediterranean stages that are characterized by contrasting plate motions and driving forces: (1) 131–84 Ma intra-oceanic plate motion subduction of the Ligurian part of Alpine Tethys attached to Iberia coincided with Eo-alpine orogenesis in the subduction Alcapia microplate, north of Africa.
    [Show full text]