TY - JOUR A1 - Candan, O. A1 - Cetinkaplan, Mete A1 - Oberhänsli, Roland A1 - Rimmele, Gaetan A1 - Akal, Cemal B. T1 - Alpine high-P/low-T metamorphism of the Afyon Zone and implications for the metamorphic evolution of Western Anatolia, Turkey N2 - Carpholite+chloritoid+pyrophyllite association occurs widely in the Triassic metaclastic rocks of the Afyon Zone in west-central Turkey. Fe-Mg-carpholite is associated with rare aragonite pseudomorphs and glaucophane in marbles and metabasites, respectively. The Afyon Zone consists stratigraphically of a Pan-African basement and an overlying Mesozoic cover sequence. The Pan-African basement, which shows Barrovian-type amphibolite-facies metamorphism, comprises garnet-mica schists, intruded by sodic amphibole-bearing metagabbros and leucocratic metagranites. It is unconformably overlain by a continuous metasedimentary sequence extending from Triassic to early Palaeocene. This cover sequence begins with metaconglomerates, which pass upwards into phyllites. Fe-Mg-carpholite occurs within this metaclastic sequence as rosette-like crystals in metapelites and fibres in quartz segregations. The metaclastic rocks are succeeded by metamorphosed platform carbonates, grading into Latest Mesozoic metamorphosed pelagic limestones, which in turn progress up to a Late Mesozoic-Early Tertiary olistostrome. This sequence is tectonically overlain by the blueschists of the Tavsanh Zone. Fe-Mg-carpholite-bearing assemblages imply temperatures of about 350 degrees C and minimum pressures of 6-9 kbar, corresponding to burial depths of about 30 km for the Mesozoic passive continental margin sediments and the underlying Pan-African supracrustal metasediments and metaintrusives. The metamorphic rocks of the Afyon Zone are unconformably overlain by Upper Palaeocene-Lower Eocene sedimentary rocks, indicating a Paleocene age for the regional HP/LT metamorphism. This implies continuous younging of HP/LT metamorphism in the Anatolides related to northward subduction of the Anatolide-Tauride platform beneath the Sakarya Zone. From north to south this involved the Tavsanh Zone (Campanian, 80 +/- 5 Ma), the Afyon Zone (Palaeocene?), the Menderes Massif (Middle Eocene) and the Lycian Nappes (Late Cretaceous-Eocene?), all of which were probably derived from the frontal part of the Anatolide-Tauride platform. (c) 2005 Elsevier B.V. All rights reserved Y1 - 2005 SN - 0024-4937 ER - TY - JOUR A1 - Rimmele, Gaetan A1 - Parra, T. A1 - Goffe, B. A1 - Oberhänsli, Roland A1 - Jolivet, L. A1 - Candan, O. T1 - Exhumation paths of high-pressure-low-temperature metamorphic rocks from the Lycian Nappes and the Menderes Massif (SW Turkey) : a multi-equilibrium approach N2 - The Menderes Massif and the overlying Lycian Nappes occupy an extensive area of SW Turkey where high-pressure- low-temperature metamorphic rocks occur. Precise retrograde P-T paths reflecting the tectonic mechanisms responsible for the exhumation of these high-pressure-low-temperature rocks can be constrained with multi-equilibrium P-T estimates relying on local equilibria. Whereas a simple isothermal decompression is documented for the exhumation of high-pressure parageneses from the southern Menderes Massif, various P-T paths are observed in the overlying Karaova Formation of the Lycian Nappes. In the uppermost levels of this unit, far from the contact with the Menderes Massif, all P-T estimates depict cooling decompression paths. These high-pressure cooling paths are associated with top-to-the-NNE movements related to the Akcakaya shear zone, located at the top of the Karaova Formation. This zone of strain localization is a local intra-nappe contact that was active in the early stages of exhumation of the high-pressure rocks. In contrast, at the base of the Karaova Formation, along the contact with the Menderes Massif, P-T calculations show decompressional heating exhumation paths. These paths are associated with severe deformation characterized by top-to-the-east shearing related to a major shear zone (the Gerit shear zone) that reflects late exhumation of high-pressure parageneses under warmer conditions Y1 - 2005 SN - 0022-3530 ER - TY - JOUR A1 - Jolivet, L. A1 - Rimmele, Gaetan A1 - Oberhänsli, Roland A1 - Goffe, B. A1 - Candan, O. T1 - Correlation of syn-orogenic tectonic and metamorphic events in the Cyclades, the Lycian nappes and the Menderes massif : Geodynamic implications N2 - The recent discovery of HP-LT parageneses in the basal unit of the Lycian nappes and in the Mesozoic cover of the Menderes massif leads us to reconsider and discuss the correlation of this region with the nearby collapsed Hellenides in the Aegean domain. Although similarities have long been pointed Out by various authors, a clear correlation has not yet been proposed and most authors insist more on differences than similarities. The Menderes massif is the eastern extension of the Aegean region but it has been less severely affected by the Aegean extension during the Oligo-Miocene. It would thus be useful to use the structure of the Menderes massif as an image of the Aegean region before a significant extension has considerably reduced its crustal thickness. But the lack of correlation between the two regions has so far hampered Such comparisons. We describe the main tectonic units and metamorphic events in the two regions and propose a correlation. We then show possible sections of the two regions before the Aegean extension and discuss the involvement of continental basement in the Hellenic accretionary complex. In our interpretation the Hellenic- Tauric accretionary complex was composed of stacked basement and cover units which underwent variable P-T histories. Those which were not exhumed early enough later followed a high-T evolution which led to partial melting in the Cyclades during post-orogenic extension. Although the Menderes massif contains a larger volume of basement units it does not show significant evidence for the Oligo-Miocene migmatites observed in the center of the Cyclades suggesting that crustal partial melting is strictly related to post-orogenic extension in this case Y1 - 2004 SN - 0037-9409 ER - TY - THES A1 - Rimmelé, Gaëtan T1 - Structural and metamorphic evolution of the Lycian Nappes and the Menderes Massif (southwest Turkey) : geodynamic implications and correlations with the Aegean domain N2 - West Anatolien, welches die östliche laterale Verlängerung der ägäischen Domäne darstellt, besteht aus mehreren tektono-metamorphen Einheiten, die Hochdruck/Niedrigtemperatur (HP/LT) Gesteine aufweisen. Einige dieser metamorphen Gesteine Zeugen der panafrikanischen oder der kimmerischen Orogenese sind, entstanden andere während die jüngere Alpine Orogenese. Das Menderes Massiv, in der SW Türkei, wird im N von Decken der Izmir-Ankara Suturzone, im E von der Afyon Zone sowie im S von den Lykischen Decken tektonisch überlagert. In den Metasedimenten der Lykischen Decken und dem darunterliegenden Menderes Massiv treten weitverbreitete Vorkommen von Fe-Mg-Carpholith-führenden Gesteinen auf. Diese neue Entdeckung belegt, dass beide Deckenkomplexe während der alpinen Orogenese unter HP/LT Bedingungen überprägt wurden. Die P-T Bedingungen für die HP-Phase liegen bei 10-12 kbar/400°C in den Lykischen Decken und 12-14 kbar/470-500°C im südlichen Menderes Massiv, was eine Versenkung von min. 30 km während der Subduktion und Deckenstapelung dokumentiert. Die Analyse der duktilen Deformation sowie thermobarometrische Berechnungen zeigen, dass die Lykischen Metasedimente unterschiedliche Exhumierungspfade nach der gemeinsamen HP-Phase durchliefen. In Gesteinen, die weiter entfernt vom Kontakt der Lykischen Decken mit dem Menderes Massiv liegen, lässt sich lediglich ein Hochdruck-Abkühlungspfad belegen, der mit einer „top-NNE“ Bewegung an die Akçakaya Scherzone gebunden ist. Diese Scherzone ist ein Intra-Deckenkontakt, der in den frühen Stadien, innerhalb des Stabilitätsfeldes von Fe-Mg-Carpholith, der Exhumierung aktiv war. Die nahe am Kontakt mit dem Menderes Massiv gelegenen Gesteine weisen wärmere Exhumierungspfade auf, die mit einer „top-E“ Scherung assoziiert sind. Diese Deformation erfolgte nach dem S-Transport der Lykischen Decken und somit zeitgleich mit der Reaktivierung des Kontakts der Lykischen Decken/Menderes Massiv als Hauptscherzone (der Gerit Scherzone), die eine späte Exhumierung der HP-Gesteine unter wärmeren Bedingungen erlaubte. Die Hochdruckgesteine des südlichen Menderes Massiv weisen eine einfache isothermale Dekompression bei etwa 450°C während der Exhumierung nach. Die begleitende Deformation während der Hochdruckphase und der Exhumierung ist durch eine starke N-S bis NE-SW–Dehnung charakterisiert. Das Alter der Hochdruckmetamorphose in den Lykischen Decken kann zwischen oberster Kreide (jüngste Sedimente in der Lykischen allochthonen Einheit) und Eozän (Kykladische Blauschiefer) festgelegt werden. Ein mögliches Paläozänes Alter kann somit angenommen werden. Das Alter der Hochdruckmetamorphose in den Deckschichten des Menderes Massiv liegt demnach zwischen mittlerem Paläozän (oberste Metaolistostrome der Menderes „Cover“-Einheit) und dem mittleren Eozän (HP-Metamorphose in der Dilek-Selçuk Region des Kykladenkomplex). Apatit-Spaltspur-Daten von beiden Seiten des Kontakts der Lykischen Decken/Menderes Massiv lassen darauf schließen, daß diese Gesteine im späten Oligozän/frühen Miozän sehr nahe der Paläo-Oberfläche waren. Die hier dargestellten Arbeiten in den Lykischen Decken und im Menderes Massiv lassen auf die Existenz eines ausgedehnten alpinen HP-Metamorphose-Gürtels im SW der Türkei schließen. Die Hochdruckgesteine wurden im Akkretionskomplex einer N-wärtigen Subduktion des Neo-Tethys Ozeans gebildet, der spät-Kretazisch obduziert und dann in die früh-Tertiäre Kontinentalkollision des passiven Randes (Anatolid-Taurid Block) mit der nördlichen Platte (Sakarya Mikrokontinent) miteinbezogen war. Im Eozän bestand der Akkretionskomplex aus drei gestapelten Hochdruckeinheiten. Die Unterste entspricht dem eingeschuppten Kern und Hochdruck-„Cover“ des Menderes Massivs. Die Mittlere besteht aus dem Kykladischen Blauschiefer-Komplex (Dilek-Selçuk Einheit) und die oberste Einheit wird von den Hochdruck Lykischen Decken gebildet. Während die Basiseinheiten der ägäischen und anatolischen Region tektonisch unterschiedliche Prä-mesozoische Geschichten durchliefen, wurden sie wahrscheinlich am Ende des Paläozikums zusammengeführt und durchliefen dann ein gemeinsame mesozoische Geschichte. Dann wurden die Basis und ihre Deckschichten, ebenso wie die Kykladischen Blauschiefer und Lykischen Decken, in ähnlich entstandene akkretionäre Komplexe während des Eozäns und Oligozäns involviert. N2 - Western Anatolia that represents the eastward lateral continuation of the Aegean domain is composed of several tectono-metamorphic units showing occurrences of high-pressure/low-temperature (HP-LT) rocks. While some of these metamorphic rocks are vestiges of the Pan-African or Cimmerian orogenies, others are the result of the more recent Alpine orogenesis. In southwest Turkey, the Menderes Massif occupies an extensive area tectonically overlain by nappe units of the Izmir-Ankara Suture Zone in the north, the Afyon Zone in the east, and the Lycian Nappes in the south. In the present study, investigations in the metasediments of the Lycian Nappes and underlying southern Menderes Massif revealed widespread occurrences of Fe-Mg-carpholite-bearing rocks. This discovery leads to the very first consideration that both nappe complexes recorded HP-LT metamorphic conditions during the Alpine orogenesis. P-T conditions for the HP metamorphic peak are about 10-12 kbar/400°C in the Lycian Nappes, and 12-14 kbar/470-500°C in the southern Menderes Massif, documenting a burial of at least 30 km during subduction and nappe stacking. Ductile deformation analysis in concert with multi-equilibrium thermobarometric calculations reveals that metasediments from the Lycian Nappes recorded distinct exhumation patterns after a common HP metamorphic peak. The rocks located far from the contact separating the Lycian Nappes and the Menderes Massif, where HP parageneses are well preserved, retained a single HP cooling path associated with top-to-the-NNE shearing related to the Akçakaya shear zone. This zone of strain localization is an intra-nappe contact that was active in the early stages of exhumation of HP rocks, within the stability field of Fe-Mg-carpholite. The rocks located close to the contact with the Menderes Massif, where HP parageneses are completely retrogressed into chlorite and mica, recorded warmer exhumation paths associated with top-to-the-E intense shearing. This deformation occurred after the southward emplacement of Lycian Nappes, and is contemporaneous with the reactivation of the ’Lycian Nappes-Menderes Massif′ contact as a major shear zone (the Gerit shear zone) that allowed late exhumation of HP parageneses under warmer conditions. The HP rocks from the southern Menderes Massif recorded a simple isothermal decompression at about 450°C during exhumation, and deformation during HP event and its exhumation is characterized by a severe N-S to NE-SW stretching. The age of the HP metamorphism recorded in the Lycian Nappes is assumed to range between the Latest Cretaceous (age of the youngest sediments in the Lycian allochthonous unit) and the Eocene (age of the Cycladic Blueschists). A probable Palaeocene age is suggested. The age of the HP metamorphism that affected the cover series of the Menderes Massif is constrained between the Middle Palaeocene (age of the uppermost metaolistostrome of the Menderes ’cover′) and the Middle Eocene (age of the HP metamorphism in the Dilek-Selçuk region that belongs to the Cycladic Complex). Apatite fission track data for the rocks on both sides of the ’Lycian Nappes/Menderes Massif’ contact suggest that these rocks were very close to the paleo-Earth surface in the Late Oligocene-Early Miocene time. This study in the Lycian Nappes and in the Menderes Massif establishes the existence of an extensive Alpine HP metamorphic belt in southwest Turkey. HP rocks were involved in the accretionary complex related to northward-verging subduction of the Neo-Tethys Ocean, Late Cretaceous obduction and subsequent Early Tertiary continental collision of the passive margin (Anatolide-Tauride block) beneath the active margin of the northern plate (Sakarya micro-continent). During the Eocene, the accretionary complex was made of three stacked HP units. The lowermost corresponds to the imbricated ’core′ and HP ’cover′ of the Menderes Massif, the intermediate one consists of the Cycladic Blueschist Complex (Dilek-Selçuk unit), and the uppermost unit is made of the HP Lycian Nappes. Whereas the basement units of both Aegean and Anatolian regions underwent a different pre-Mesozoic tectonic history, they were probably juxtaposed by the end of the Paleozoic and underwent a common Mesozoic history. Then, the basements and their cover, as well as the Cycladic Blueschists and the Lycian Nappes were involved in similar evolutional accretionary complexes during the Eocene and Oligocene times. KW - Fe-Mg-carpholite KW - Menderes Massiv KW - Lykischen Decken KW - West Türkei KW - Hochdruck/Niedrigtemperatur Gesteine KW - Fe-Mg-carpholite KW - Menderes Massif KW - Lycian Nappes KW - West Turkey KW - High-pressure/low-temperature rocks Y1 - 2003 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-0001094 ER -