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Seismic crust structure beneath the Aegean region in southwest Turkey from radial anisotropic inversion of Rayleigh and Love surface waves

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EN
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The Turkish plate is covered by hundreds of accelerometer and broadband seismic stations with less than 50 km inter-station distance providing high-quality earthquake recordings within the last decade. We utilize part of these stations to extract the fundamental mode Rayleigh and Love surface wave phase and group velocity data in the period range 5–20 s to determine the crust structure beneath the Aegean region in southwest Turkey. The observed surface wave signals are interpreted using both single-station and two-station techniques. A tomographic inversion technique is employed to obtain the two-dimensional group velocity maps from the single-station group velocities. One-dimensional velocity–depth profiles under each twodimensional mesh point, which are jointly interpreted to acquire the three-dimensional image of the shear-wave velocities underneath the study area, are attained by utilizing the least-squares inversion technique, which is repeated for both Rayleigh and Love surface waves. The isotropic crust structure cannot jointly invert the observed Rayleigh and Love surface waves where the radial anisotropic crust better describes the observed surface wave data. The intrusive magmatic activity related to the northward subducting African plate under the Turkish plate results the crust structure deformations, which we think, causing the observed radial anisotropy throughout complex pattern of dykes and sills. The magma flow resulting in the mineral alignment within dykes and sills contributes to the observed anisotropy. Due to the existence of dykes, the radial anisotropy in the upper crust is generally negative, i.e., vertically polarized S-waves (Vsv) are faster than horizontally polarized S-waves (Vsh). Due to the existence of sills, the radial anisotropy in the middle-to-lower crust is generally positive, i.e., horizontally polarized S-waves (Vsh) are faster than vertically polarized S-waves (Vsv). Similar radial anisotropic results to those of the single-station analyses are obtained by the two-station analyses utilizing the cross-correlograms. The widespread volcanic and plutonic rocks in the region are consistent with the current seismic interpretations of the crustal deformations.
Czasopismo
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1303--1340
Opis fizyczny
Bibliogr. 202 poz.
Twórcy
autor
  • Çanakkale, Turkey
Bibliografia
  • 1. AFAD (2017) Strong ground motion database of Türkiye (TR-NSMN). Disaster and Emergency Management Presidency, Ankara
  • 2. Agius MR, Lebedev S (2014) Shear-velocity structure, radial anisotropy and dynamics of the Tibetan crust. Geophys J Int 199:1395–1415
  • 3. Agostini S, Doglioni C, Innocenti F, Manetti P, Tonarini S (2010) On the geodynamics of the Aegean rift. Tectonophysics 488:7–21
  • 4. Akay E, Işintek I, Erdoğan B, Hasözbek A (2011) Stratigraphy of the Afyon Zone around Emet (Kütahya, NW Anatolia) and geochemical characteristics of the Triassic volcanism along the northern Menderes Massif. Neues Jahrbuch Für Mineralogie—Abhandlungen 188:297–316
  • 5. Akbaş B, Akdeniz N, Aksay A, Altun İ, Balcı V, Bilginer E, Bilgiç T, Duru M, Ercan T, Gedik İ, Günay Y, Güven İH, Hakyemez HY, Konak N, Papak İ, Pehlivan Ş, Sevin M, Şenel M, Tarhan N, Turhan N, Türkecan A, Ulu Ü, Uğuz MF, Yurtsever A et al (2017) Geological map of Turkey. MTA (General Directorate of Mineral Research and Exploration of Turkey) Publications, Ankara
  • 6. Altıner D, Koçyiğit A, Farinacci A, Nicosia U, Conti MA (1991) Jurassic, Lower Cretaceous stratigraphy and paleogeographic evolution of the southern part of the northwestern Anatolia. Geol Rom 18:13–80
  • 7. Altunkaynak S (2007) Collision-driven slab breakoff magmatism in northwestern Anatolia, Turkey. J Geol 115:63–82
  • 8. Altunkaynak Ş, Dilek Y, Genç CŞ, Sunal G, Gertisser R, Furnes H, Foland KA, Yang J (2012) Spatial, temporal and geochemical evolution of Oligo–Miocene granitoid magmatism in western Anatolia, Turkey. Gondwana Res 21:961–986
  • 9. Anderson DL (1961) Elastic wave propagation in layered anisotropic media. J Geophys Res 66:2953–2963
  • 10. Anderson DL (1989) Theory of the Earth. Blackwell Scientific Publications, Oxford
  • 11. Arslan A, Güngör T, Erdoğan B, Passchier CW (2013) Tectonic transport directions of the Lycian nappes in southwest Turkey constrained by kinematic indicators. J Asian Earth Sci 64:198–209
  • 12. Aydemir A (2009) Tectonic investigation of Central Anatolia, Turkey, using geophysical data. J Appl Geophys 68:321–334
  • 13. Backus GE (1962) Long-wave anisotropy produced by horizontal layering. J Geophys Res 66:4427–4440
  • 14. Bakırcı T, Yoshizawa K, Özer MF (2012) Three-dimensional S-wave structure of the upper mantle beneath Turkey from surface wave tomography. Geophys J Int 190:1058–1076
  • 15. Baran Z, Dilek Y, Kadioglu YK (2010) Geology and geochemistry of the synextensional Salihli granitoid in the Menderes core complex, western Anatolia, Turkey. Int Geol Rev 52:336–368
  • 16. Bastow ID, Pilidou S, Kendall J-M, Stuart GW (2010) Melt-induced seismic anisotropy and magma assisted rifting in Ethiopia: evidence from surface waves. Geochem Geophys Geosyst 11:Q0AB05. https://doi.org/10.1029/2010GC003036
  • 17. Behr Y, Townend J, Bannister S, Savage MK (2011) Crustal shear wave tomography of the Taupo Volcanic Zone, New Zealand, via ambient noise correlation between multiple three-component networks. Geochem Geophys Geosyst 12:Q03015. https://doi.org/10.1029/2010GC003385
  • 18. Beucler É, Stutzmann É, Montagner JP (2003) Surface wave higher-mode phase velocity measurements using a roller-coaster-type algorithm. Geophys J Int 155:289–307
  • 19. Bingöl E, Akyürek B, Korkmazer B (1975) Geology of the Biga peninsula and some characteristics of the Karakaya blocky series. In: Proceedings of the Congress of Earth Sciences on the Occasion of the 50th Anniversary of the Turkish Republic. General Directorate of Mineral Research and Exploration of Turkey (MTA), Ankara, pp 71–77
  • 20. Biryol CB, Beck SL, Zandt G, Özacar AA (2011) Segmented African lithosphere beneath the Anatolian region inferred from teleseismic P-wave tomography. Geophys J Int 184:1037–1057
  • 21. Bonev N, Beccaletto L (2007) From syn-to post-orogenic Tertiary extension in the north Aegean region: constraints on the kinematics in the eastern Rhodope–Thrace, Bulgaria–Greece and the Biga Peninsula, NW Turkey. Geol Soc Lond Spec Publ 291:113–142. https://doi.org/10.1144/SP291.6
  • 22. Bozkurt E (2004) Granitoid rocks of the southern Menderes Massif (Southwest Turkey): field evidence for Tertiary magmatism in an extensional shear zone. Int J Earth Sci 93:52–71
  • 23. Bozkurt E, Oberhänsli R (2001) Menderes Massif (Western Turkey): structural, metamorphic and magmatic evolution—a synthesis. Int J Earth Sci 89:679–708
  • 24. Brocher TM (2005) Empirical relations between elastic wavespeeds and density in the Earth’s crust. Bull Seismol Soc Am 95:2081–2092
  • 25. Burchardt S (2008) New insights into the mechanics of sill emplacement provided by field observations of the Njardvik Sill, Northeast Iceland. J Volcanol Geotherm Res 173:280–288
  • 26. Çakır Ö, Erduran M (2001) Effect of earth structure and source time function on inversion of single station regional surface waves for rupture mechanism and focal depth. J Balk Geophys Soc 4:69–90
  • 27. Cambaz MD, Karabulut H (2010) Love-wave group velocity maps of Turkey and surrounding regions. Geophys J Int 181:502–520
  • 28. Candan O, Dora OÖ, Oberhänsli R, Çetinkaplan M, Partzsch JH, Warkus FC, Dürr S (2001) Pan-African high-pressure metamorphism in the Precambrian basement of the Menderes Massif, western Anatolia, Turkey. Int J Earth Sci 89:793–811
  • 29. Candan O, Çetinkaplan M, Oberhänsli R, Rimmelé G, Akal C (2005) Alpine high-P/low-T metamorphism of the Afyon Zone and implications for the metamorphic evolution of Western Anatolia, Turkey. Lithos 84:102–124
  • 30. Çelik ÖF, Delaloye M (2003) Origin of metamorphic sole rocks and their post kinematic mafic dyke swarms in the Antalya and Lycian ophiolites, SW Turkey. Geol J 38:235–256
  • 31. Chan J, Schmitt DR (2015) Elastic anisotropy of a metamorphic rock sample of the Canadian Shield in Northeastern Alberta. Rock Mech Rock Eng 48:1369–1385
  • 32. Cho K-H, Herrmann RB, Ammon CJ, Lee K (2007) Imaging the upper crust of the Korean Peninsula by surface-wave tomography. Bull Seism Soc Am 97:198–207
  • 33. Cho K-H, Chen H-W, Kang I-B, Lee S-H (2011) Crust and upper mantle structures of the region between Korea and Taiwan by surface wave dispersion study. Geosci J 15:71–81. https://doi.org/10.1007/s12303-011-0009-9
  • 34. Çınar H, Alkan H (2016) Crustal S-wave structure beneath Eastern Black Sea Region revealed by Rayleigh-wave group velocities. J Asian Earth Sci 115:273–284
  • 35. Collins AS, Robertson AHF (1997) Lycian mélange, southwest Turkey: an emplaced Cretaceous accretionary complex. Geology 25:255–258
  • 36. Crampin S (1984) Effective anisotropic elastic constants for wave propagation through cracked solids. Geophys J R Astron Soc 76:135–145
  • 37. Çubuk-Sabuncu Y, Taymaz T, Fichtner A (2017) 3-D crustal velocity structure of western Turkey: constraints from full-waveform tomography. Phys Earth Planet Inter 270:90–112
  • 38. Delaloye M, Bingöl E (2000) Granitoids from western and northwestern Anatolia: geochemistry and modeling of geodynamic evolution. Int Geol Rev 42:241–268
  • 39. Delph JR, Biryol CB, Beck SL, Zandt G, Ward KM (2015) Shear wave velocity structure of the Anatolian Plate: anomalously slow crust in southwestern Turkey. Geophys J Int 202:261–276
  • 40. Demirtasli E, Turhan N, Bilgin AZ, Selim M (1984) Geology of the Bolkar Mountains. In: Tekeli O, Göncüoğlu MC (eds) Geology of the Taurus Belt, Proceedings of the International Symposium, Ankara-Turkey, pp 125–141
  • 41. Dias RC, Julià J, Schimmel M (2015) Rayleigh-wave, group-velocity tomography of the Borborema Province, NE Brazil, from ambient seismic noise. Pure appl Geophys 172:1429–1449
  • 42. Dilek Y, Altunkaynak Ş (2009) Geochemical and temporal evolution of Cenozoic magmatism in western Turkey: mantle response to collision, slab break-off, and lithospheric tearing in an orogenic belt. Geol Soc Lond Spec Publ 311:213–233
  • 43. Dilek Y, Altunkaynak Ş (2010) Geochemistry of Neogene—quaternary alkaline volcanism in western Anatolia, Turkey, and implications for the Aegean mantle. Int Geol Rev 52:631–655
  • 44. Dilek Y, Sandvol E (2009) Seismic structure, crustal architecture and tectonic evolution of the Anatolian-African plate boundary and the Cenozoic Orogenic Belts in the Eastern Mediterranean Region. Geol Soc Lond Spec Publ 327:127–160
  • 45. Dilek Y, Altunkaynak Ş, Öner Z (2009) Syn-extensional granitoids in the Menderes core complex, and the late Cenozoic extensional tectonics of the Aegean Province. In: Ring U, Wernicke B (eds) Extending a continent: architecture, rheology and heat budget, vol 321. Geological Society of London (Special Publications), London, pp 197–223
  • 46. Dogru F, Pamukcu O, Gonenc T, Yildiz H (2018) Lithospheric structure of western Anatolia and the Aegean Sea using GOCE-based gravity field models. Bollettino di Geofisica Teorica ed Applicata 59:135–160
  • 47. Dziewonski AM, Anderson DL (1981) Preliminary reference Earth model. Phys Earth Planet Inter 25:297–356
  • 48. Dziewonski AM, Hales AL (1972) Numerical analysis of dispersed seismic waves. In: Methods in computational physics: advances in research and applications, vol 11, pp 39–85
  • 49. Dziewonski A, Bloch S, Landisman M (1969) A technique for the analysis of transient seismic signals. Bull Seismol Soc Am 59:427–444
  • 50. Dziewonski AM, Chou T-A, Woodhouse JH (1981) Determination of earthquake source parameters from waveform data for studies of global and regional seismicity. J Geophys Res 86:2825–2852. https://doi.org/10.1029/JB086iB04p02825
  • 51. Ekström G, Nettles M, Dziewonski AM (2012) The global CMT project 2004-2010: centroid-moment tensors for 13,017 earthquakes. Phys Earth Planet Inter 200–201:1–9. https://doi.org/10.1016/j.pepi.2012.04.002
  • 52. Emre Ö, Duman TY, Özalp S, Elmacı H, Olgun Ş, Şaroğlu F (2013) Active faults map of Turkey (scale:1/1.125.000). MTA (General Directorate of Mineral Research and Exploration of Turkey) Publications, Ankara
  • 53. Endrun B, Meier T, Lebedev S, Bohnhoff M, Stavrakakis G, Harjes H-P (2008) S velocity structure and radial anisotropy in the Aegean region from surface wave dispersion. Geophys J Int 174:593–616
  • 54. Erduran M (2009) Teleseismic inversion of crustal S-wave velocities beneath the Isparta Station. J Geodyn 47:225–236
  • 55. Erduran M, Endrun B, Meier T (2008) Continental versus oceanic lithosphere beneath the eastern Mediterranean Sea—implications from Rayleigh wave dispersion measurements. Tectonophysics 457:42–52
  • 56. Ersoy YE, Helvacı C, Sözbilir H (2010) Tectono-stratigraphic evolution of the NE–SW-trending superimposed Selendi basin: implications for late Cenozoic crustal extension in Western Anatolia,Turkey. Tectonophysics 488:210–232
  • 57. Faccenda M, Capitanio FA (2013) Seismic anisotropy around subduction zones: insights from three dimensional modeling of upper mantle deformation and SKS splitting calculations. Geochem Geophys Geosyst 14:1–20. https://doi.org/10.1029/2012GC004451
  • 58. Feng M, Assumpção M, Van der Lee S (2004) Group-velocity tomography and lithospheric S-velocity structure of the South American continent. Phys Earth Planet Inter 147:315–331
  • 59. Fichtner A, Villaseñor A (2015) Crust and upper mantle of the western Mediterranean—constraints from full-waveform inversion. Earth Planet Sci Lett 428:52–62
  • 60. Friederich W (2003) The S-velocity structure of the East Asian mantle from inversion of shear and surface waveforms. Geophys J Int 153:88–102
  • 61. Fu YV, Li A (2015) Crustal shear wave velocity and radial anisotropy beneath the Rio Grande rift from ambient noise tomography. J Geophys Res 120:1005–1019. https://doi.org/10.1002/2014JB011602
  • 62. GEOSIG (2012) Geosig, AC-73 triaxial force balance accelerometer. http://www.seismicsystems.net/images/pdfs/GS_AC-73_Leaflet_V12.pdf. Accessed 24 July 2017
  • 63. Gessner K, Gallardo LA, Markwitz V, Ring U, Thomson SN (2013) What caused the denudation of the Menderes Massif: review of crustal evolution, lithosphere structure, and dynamic topography in southwest Turkey. Gondwana Res 24:243–274
  • 64. Gessner K, Gallardo LA, Wedin F, Sener K (2016) Crustal structure of the northern Menderes Massif, western Turkey, imaged by joint gravity and magnetic inversion. Int J Earth Sci 105:2133–2148
  • 65. Gessner K, Markwitz V, Güngör T (2017) Crustal fluid flow in hot continental extension: tectonic framework of geothermal areas and mineral deposits in western Anatolia. Geol Soc Lond Spec Publ 453:289–311
  • 66. Godfrey HJ, Fry B, Savage MK (2017) Shear-wave velocity structure of the Tongariro Volcanic Centre, New Zealand: fast Rayleigh and slow Love waves indicate strong shallow anisotropy. J Volcanol Geotherm Res 336:33–50
  • 67. Gök R, Mellors RJ, Sandvol E, Pasyanos M, Hauk T, Takedatsu R, Yetirmishli G, Teoman U, Turkelli N, Godoladze T, Javakishvirli Z (2011) Lithospheric velocity structure of the Anatolian plateau-Caucasus-Caspian region. J Geophys Res 116:B05303. https://doi.org/10.1029/2009JB000837
  • 68. Görür N, Tüysüz O, Şengör AMC (1998) Tectonic evolution of the Central Anatolian basins. Int Geol Rev 40:832–850
  • 69. Govers R, Fichtner A (2016) Signature of slab fragmentation beneath Anatolia from full-waveform tomography. Earth Planet Sci Lett 450:10–19
  • 70. GURALP (2013) Guralp systems, CMG-5TD digital accelerometer, operator’s guide. https://www.guralp.com/documents/MAN-050-0005.pdf. Accessed 20 July 2017
  • 71. Gursoy H, Piper JDA, Tatar O, Mesci L (1998) Paleomagnetic study of the Karaman and Karapinar olcanic complexes, Central Turkey: neotectonic rotation in the south-central sector of the Anatolian Block. Tectonophysics 299:191–211
  • 72. Gürsu S, Göncüoğlu MC, Bayhan H (2004) Geology and geochemistry of the pre-early Cambrian rocks in the Sandikli area: implications for the Pan-African evolution of NW Gondwanaland. Gondwana Res 7:923–935
  • 73. Hacker BR, Ritzwoller MH, Xie J (2014) Partially melted, micabearing crust in Central Tibet. Tectonics 33:1408–1424. https://doi.org/10.1002/2014TC003545
  • 74. Hall J, Aksu AE, Elitez I, Yaltırak C, Çifçi G (2014a) The Fethiye–Burdur Fault Zone: a component of upper plate extension of the subduction transform edge propagator fault linking Hellenic and Cyprus Arcs, Eastern Mediterranean. Tectonophysics 635:80–99
  • 75. Hall J, Aksu AE, King H, Gogacz A, Yaltırak C, Çifçi G (2014b) Miocene—recent evolution of the western Antalya Basin and its linkage with the Isparta Angle, eastern Mediterranean. Mar Geol 349:1–23
  • 76. Harmon N, Rychert CA (2015) Seismic imaging of deep crustal melt sills beneath Costa Rica suggests a method for the formation of the Archean continental crust. Earth Planet Sci Lett 430:140–148
  • 77. Haskell NA (1953) The dispersion of surface waves on multilayered media. Bull. Seism. Soc. Am. 43:17–34
  • 78. Heineke C, Niedermann S, Hetzel R, Akal C (2016) Surface exposure dating of Holocene basalt flows and cinder cones in the Kula volcanic field (Western Turkey) using cosmogenic 3He and 10Be. Quat Geochronol 34:81–91
  • 79. Herrin E, Goforth T (1977) Phase-matched filters: application to the study of Rayleigh waves. Bull Seismol Soc Am 67:1259–1275
  • 80. Herrmann RB (1973) Some aspects of band-pass filtering of surface waves. Bull Seismol Soc Am 63:663–671
  • 81. Herrmann RB (2002) Computer programs in seismology, version 3.30. St. Louis University, Missouri
  • 82. Hetzel R, Ring U, Akal C, Troesch M (1995) Miocene NNE-directed extensional unroofing in the Menderes Massif, southwestern Turkey. J Geol Soc Lond 152:639–654
  • 83. Hier-Majumder S, Drombosky T (2015) Development of anisotropic contiguity in deforming partially molten aggregates: 2. Implications for the lithosphere–asthenosphere boundary. J Geophys Res Solid Earth 120:764–777. https://doi.org/10.1002/2014JB011454
  • 84. İlkışık OM (1995) Regional heat flow in western Anatolia using silica temperature estimates from thermal springs. Tectonophysics 244:175–184
  • 85. Işık V, Tekeli O (2001) Late orogenic crustal extension in the northern Menderes massif (western Turkey): evidence for metamorphic core complex formation. Int J Earth Sci 89:757–765
  • 86. Janssen C, Bohnhoff M, Vapnik Y, Görgün E, Bulut F, Plessen B, Pohl D, Aktar M, Okay AI, Dresen G (2009) Tectonic evolution of the Ganos segment of the North Anatolian Fault (NW Turkey). J Struct Geol 31:11–28
  • 87. Jaxybulatov K, Shapiro NM, Koulakov I, Mordret A, Landès M, Sens-Schönfelder C (2014) A large magmatic sill complex beneath the Toba caldera. Science 346:617–619
  • 88. Ji S, Salisbury MH (1993) Shear-wave velocities, anisotropy and splitting in high-grade mylonites. Tectonophysics 221:453–473
  • 89. Ji S, Shao T, Michibayashi K, Oya S, Satsukawa T, Wang Q, Zhao W, Salisbury MH (2015) Magnitude and symmetry of seismic anisotropy in mica- and amphibole-bearing metamorphic rocks and implications for tectonic interpretation of seismic data from the southeast Tibetan Plateau. J Geophys Res Solid Earth 120:6404–6430. https://doi.org/10.1002/2015JB012209
  • 90. Jin G, Gaherty JB (2015) Surface wave phase-velocity tomography based on multichannel cross-correlation. Geophys J Int 201:1383–1398
  • 91. Johnson LR, Wenk HR (1974) Anisotropy of physical properties in metamorphic rocks. Tectonophysics 23:79–98
  • 92. Jolivet L, Brun J-P (2010) Cenozoic geodynamic evolution of the Aegean. Int J Earth Sci 99:109–138
  • 93. Jolivet L, Faccenna C, Huet B, Labrousse L, Le Pourhiet L, Lacombe O, Lecomte E, Burov E, Denèle Y, Brun J-P, Philippon M, Paul A, Salaün G, Karabulut H, Piromallo C, Monié P, Gueydan F, Okay AI, Oberhänsli R, Pourteau A, Augier R, Gadenne L, Driussi O (2013) Aegean tectonics: strain localisation, slab tearing and trench retreat. Tectonophysics 597–598:1–33
  • 94. Julià J, Ammon CJ, Herrmann RB, Correig AM (2000) Joint inversion of receiver function and surface wave dispersion observations. Geophys J Int 143:99–112
  • 95. Karagianni EE, Papazachos CB (2007) Shear velocity structure in the Aegean region obtained by joint inversion of Rayleigh and Love waves. Geol Soc Lond Spec Publ 291:159–181
  • 96. Karagianni EE, Papazachos CB, Panagiotopoulos DG, Suhadolc P, Vuan A, Panza GF (2005) Shear velocity structure in the Aegean area obtained by inversion of Rayleigh waves. Geophys J Int 160:127–143
  • 97. Karaoğlu Ö, Helvacı C (2014) Isotopic evidence for a transition from subduction to slab-tear related volcanism in western Anatolia, Turkey. Lithos 192:226–239
  • 98. Karato S, Jung H, Katayama I, Skemer P (2008) Geodynamic significance of seismic anisotropy of the upper mantle: new insights from laboratory studies. Annu Rev Earth Planet Sci 36:59–95
  • 99. Kaya C (2010) Deep crustal structure of northwestern part of Turkey. Tectonophysics 489:227–239
  • 100. Kaymakci N, Özçelik Y, White SH, van Dijk PM (2009) Tectono-stratigraphy of the Çankiri Basin: late Cretaceous to early Miocene evolution of the Neotethyan suture zone in Turkey. In: van Hinsbergen DJJ, Edwards MA, Govers R (eds) Collision and collapse at the Africa–Arabia–Eurasia subduction zone, vol 311. Geological Society of London (Special Publication), London, pp 67–106
  • 101. Ketin I (1966) Tectonic units of Anatolia (Asia Minor). Miner Resour Explor Inst Turk (MTA) Bull 66:22–34
  • 102. Ko B, Jung H (2015) Crystal preferred orientation of an amphibole experimentally deformed by simple shear. Nat Commun 6:6586. https://doi.org/10.1038/ncomms7586
  • 103. Koçyiğit A, Özacar AA (2003) Extensional neotectonic regime through the NE edge of the Outer Isparta Angle, SW Turkey: new field and seismic data. Turk J Earth Sci 12:67–90
  • 104. Le Pichon X, Angelier J (1979) The Hellenic arc and trench system: a key to the neotectonic evolution of the eastern Mediterranean area. Tectonophysics 60:1–42
  • 105. Lebedev S, Adam JM-C, Meier T (2013) Mapping the Moho with seismic surface waves: a review, resolution analysis, and recommended inversion strategies. Tectonophysics 609:377–394
  • 106. Lees JM (2007) Seismic tomography of magmatic systems. J Volcanol Geotherm Res 167:37–56
  • 107. Levshin A, Ratnikova L, Berger J (1992) Peculiarities of surface- wave propagation across central Eurasia. Bull Seismol Soc Am 82:2464–2493
  • 108. Levshin AL, Ritzwoller MH, Resovsky JS (1999) Source effects on surface wave group travel times and group velocity maps. Phys Earth Planet Inter 115:293–312
  • 109. Li A, Forsyth DW, Fischer KM (2003) Shear velocity structure and azimuthal anisotropy beneath eastern North America from Rayleigh wave inversion. J Geophys Res 108(B8):2362. https://doi.org/10.1029/2002JB002259
  • 110. Licciardia A, Eken T, Taymaz T, Agostinettic NP, Yolsal-Çevikbilen S (2018) Seismic anisotropy in central North Anatolian Fault Zone and its implications on crustal deformation. Phys Earth Planet Inter 277:99–112
  • 111. Lin FC, Moschetti MP, Ritzwoller MH (2008) Surface wave tomography of the western United States from ambient seismic noise: Rayleigh and Love wave phase velocity maps. Geophys J Int 173:281–298
  • 112. Long MD, Becker TW (2010) Mantle dynamics and seismic anisotropy. Earth Planet Sci Lett 297:341–354
  • 113. Mahan K (2006) Retrograde mica in deep crustal granulites: implications for crustal seismic anisotropy. Geophys Res Lett 33:L24301. https://doi.org/10.1029/2006GL028130
  • 114. Mcclusky S, Balassanian S, Barka A, Demir C, Ergintav S, Georgiev I, Gurkan O, Hamburger M, Hurst K, Kahle HG, Kastens K, Kekelidze G, King R, Kotzev V, Lenk O, Mahmoud S, Mishin A, Nadariya M, Ouzounis A, Veis G (2000) Global Positioning System constraints on plate kinematics and dynamics in the eastern Mediterranean and Caucasus. J Geophys Res 105:5695–5719
  • 115. McMechan GA, Yedlin MJ (1981) Analysis of dispersive waves by wave field transformation. Geophysics 46:869–874
  • 116. Meier T, Dietrich K, Stöckhert B, Harjes H-P (2004) One-dimensional models of shear wave velocity for the eastern Mediterranean obtained from the inversion of Rayleigh wave phase velocities and tectonic implications. Geophys J Int 156:45–58
  • 117. Montagner JP (2007) Deep Earth structure—upper mantle structure: global isotropic and anisotropic elastic tomography. In: Dziewonski AM, Romanowicz B (eds) Treatise on geophysics, volume 1: seismology and structure of the Earth. Elsevier, Amsterdam, pp 559–590
  • 118. Montagner J-P, Anderson DL (1989) Petrological constraints on seismic anisotropy. Phys Earth Planet Inter 54:82–105. https://doi.org/10.1016/0031-9201(89)90189-1
  • 119. Montagner J-P, Nataf H-C (1986) A simple method for inverting the azimuthal anisotropy of surface waves. J Geophys Res 91:511–520. https://doi.org/10.1029/JB091iB01p00511
  • 120. Mordret A, Rivet D, Landès M, Shapiro NM (2015) Three-dimensional shear velocity anisotropic model of Piton de la Fournaise Volcano (La Réunion Island) from ambient seismic noise. J Geophys Res Solid Earth 120:406–427. https://doi.org/10.1002/2014JB011654
  • 121. Moschetti MP, Ritzwoller MH, Shapiro NM (2007) Surface wave tomography of the western United States from ambient seismic noise: Rayleigh wave group velocity maps. Geochem Geophys Geosyst 8:Q08010. https://doi.org/10.1029/2007GC001655
  • 122. Mottaghi AA, Rezapour M, Korn M (2013) Ambient noise surface wave tomography of the Iranian Plateau. Geophys J Int 193:452–462
  • 123. MTA (2002) Geological map of Turkey (scale:1/500000). MTA (General Directorate of Mineral Research and Exploration of Turkey) Publications, Ankara
  • 124. Nolet G (1990) Partitioned waveform inversion and two-dimensional structure under the network of autonomously recording seismographs. J Geophys Res 95(B6):8499–8512
  • 125. Oberhänsli R, Candan O, Dora ÖO, Dürr SH (1997) Eclogites within the Menderes Massif/Western Turkey. Lithos 41:135–150
  • 126. Oberhänsli R, Partzsch J, Candan O, Cetinkaplan M (2001) First occurrence of Fe–Mg–carpholite documenting a high-pressure metamorphism in metasediments of the Lycian Nappes, SW Turkey. Int J Earth Sci 89:867–873
  • 127. Obrebski M, Kiselev S, Vinnik L, Montagner J-P (2010) Anisotropic stratification beneath Africa from joint inversion of SKS and P receiver functions. J Geophys Res 115:1–15. https://doi.org/10.1029/2009JB006923
  • 128. Okay AI (1986) High-pressure/low-temperature metamorphic rocks of Turkey. Geol Soc Am Mem 164:333–347
  • 129. Okay AI (1989) Geology of the Menderes Massif and the Lycian Nappes south of Denizli, western Taurides. Miner Resour Explor Bull 109:37–51
  • 130. Okay AI (2001) Stratigraphic and metamorphic inversions in the central Menderes Massif: a new structural model. Int J Earth Sci 89:709–727
  • 131. Okay AI (2008) Geology of Turkey: a synopsis. Anschnitt 21:19–42
  • 132. Okay AI, Satır M (2000) Coeval plutonism and metamorphism in a latest Oligocene metamorphic core complex in northwest Turkey. Geol Mag 137:495–516
  • 133. Okay AI, Tüysüz O (1999) Tethyan sutures of northern Turkey. In: Durand B, Jolivet L, Horváth D, Sérranne M (eds) The Mediterranean basins: tertiary extension within the Alpine Orogen, vol 156. Geological Society of London (Special Publication), London, pp 475–515
  • 134. Okay AI, Siyako M, Bürkan KA (1991) Geology and tectonic evolution of the Biga Peninsula, northwest Turkey. Bull Tech Univ Istanb 44:191–256
  • 135. Okay AI, İşintek İ, Altıner D, Özkan-Altıner S, Okay N (2012) An olistostrome–mélange belt formed along a suture: Bornova Flysch zone, western Turkey. Tectonophysics 568–569:282–295
  • 136. Özbakır AD, Govers R, Wortel R (2017) Active faults in the Anatolian-Aegean plate boundary region with Nubia. Turk J Earth Sci 26:30–56
  • 137. Özbek A, Gül M, Karacan K, Alca Ö (2018) Anisotropy effect on strengths of metamorphic rocks. J Rock Mech Geotech Eng 10:164–175
  • 138. Ozer C, Gok E, Polat O (2018) Three-dimensional seismic velocity structure of the Aegean Region of Turkey from local earthquake tomography. Ann Geophys 61, 1:SE111. https://doi.org/10.4401/ag-7543
  • 139. Özgül N (1984) Stratigraphy and tectonic evolution of the Central Taurides. In: Tekeli O, Göncüoğlu MC (eds) Geology of the Taurus Belt, Proceedings of the International Symposium on the Geology of the Taurus Belt, 1983, Ankara-Turkey, Mineral Research and Exploration Institute of Turkey, Ankara, pp 77–90
  • 140. Parsons T, Sleep NH, Thompso GA (1992) Host rock rheology controls on the emplacement of tabular intrusions: implications for underplating of extending crust. Tectonics 11:1348–1356
  • 141. Pearce FD, Rondenay S, Sachpazi M, Charalampakis M, Royden LH (2012) Seismic investigation of the transition from continental to oceanic subduction along the western Hellenic Subduction Zone. J Geophys Res 117:B07306. https://doi.org/10.1029/2011JB009023
  • 142. Petford N, Clemens JC, Vigneresse JL (1997) Application of information theory to the formation of granitic rocks. In: Bouchez JL, Hutton DHW, Stephens WE (eds) Granite: from segregation of melt to emplacement fabrics. Kluwer, Dordrecht, pp 3–10
  • 143. Piromallo C, Morelli A (2003) P wave tomography of the mantle under the Alpine-Mediterranean area. J Geophys Res 108:2065. https://doi.org/10.1029/2002JB001757
  • 144. Polat G, Özel NM, Koulakov I (2016) Investigating P- and S-wave velocity structure beneath the Marmara region (Turkey) and the surrounding area from local earthquake tomography. Earth Planets Space 68:132. https://doi.org/10.1186/s40623-016-0503-4
  • 145. Portner DE, Delph JR, Biryol CB, Beck SL, Zandt G, Özacar AA, Sandvol E, Türkelli N (2018) Subduction termination through progressive slab deformation across Eastern Mediterranean subduction zones from updated P-wave tomography beneath Anatolia. Geosphere 14:907–925
  • 146. Pourteau A, Oberhänsli R, Candan O, Barrier E, Vrielynck B (2015) Neotethyan closure history of western Anatolia: a geodynamic discussion. Int J Earth Sci 105:203–224
  • 147. Purvis M, Robertson A (2005) Sedimentation of the Neogene–Recent Alaşehir (Gediz) continental graben system used to test alternative tectonic models for western (Aegean) Turkey. Sediment Geol 173:373–408
  • 148. Rawlinson N, Sambridge M (2003) Seismic traveltime tomography of the crust and lithosphere. Adv Geophys 46:81–198
  • 149. Rawlinson N, Sambridge M (2004a) Multiple reflection and transmission phases in complex layered media using a multistage fast marching method. Geophysics 69:1338–1350
  • 150. Rawlinson N, Sambridge M (2004b) Wavefront evolution in strongly heterogeneous layered media using the fast marching method. Geophys J Int 156:631–647
  • 151. Rawlinson N, Sambridge M (2005) The fast marching method: an effective tool for tomographic imaging and tracking multiple phases in complex layered media. Explor Geophys 36:341–350
  • 152. Rimmelé G, Jolivet L, Oberhänsli R, Goffé B (2003a) Deformation history of the high-pressure Lycian Nappes and implications for tectonic evolution of SW Turkey. Tectonics 22:1007. https://doi.org/10.1029/2001TC901041
  • 153. Rimmelé G, Oberhänsli R, Goffé B, Jolivet L, Candan O, Çetinkaplan M (2003b) First evidence of high-pressure metamorphism in the “Cover Series” of the southern Menderes Massif. Tectonic and metamorphic implications for the evolution of SW Turkey. Lithos 71:19–46
  • 154. Rimmelé G, Parra T, Goffé B, Oberhänsli R, Jolivet L, Candan O (2005) Exhumation paths of high-pressure–low-temperature metamorphic rocks from the Lycian Nappes and the Menderes Massif (SW Turkey): a multi-equilibrium approach. J Petrol 46:641–669
  • 155. Ring U, Layer PW (2003) High-pressure metamorphism in the Aegean, eastern Mediterranean: underplating and exhumation from the Late Cretaceous until the Miocene to Recent above the retreating Hellenic subduction zone. Tectonics 22:1022. https://doi.org/10.1029/2001TC001350
  • 156. Ring U, Johnson C, Hetzel R, Gessner K (2003) Tectonic denudation of a Late Cretaceous–Tertiary collisional belt: regionally symmetric cooling patterns and their relation to extensional faults in the Anatolide belt of western Turkey. Geol Mag 140:421–441
  • 157. Ritzwoller MH, Levshin AL (1998) Eurasian surface wave tomography: group velocities. J Geophys Res 103(B3):4839–4878
  • 158. Roche V, Laurent V, Cardello GL, Jolivet L, Scaillet S (2016) Anatomy of the Cycladic Blueschist Unit on Sifnos Island (Cyclades, Greece). J Geodyn 97:62–87
  • 159. Salaün G, Pedersen H, Paul A, Farra V, Karabulut H, Hatzfeld D, Papazachos C, Childs DM, Pequegnat C, The SIMBAAD Team (2012) High-resolution surface wave tomography of the Aegean-Anatolia region: constraints on upper mantle structure. Geophys J Int 190:406–420
  • 160. SARA (2017) Sara electronics instruments, SA10 force balance accelerometer. http://www.sara.pg.it/documents/commercial/SA10_DATASHEET_ENG.PDF. Accessed 26 July 2017
  • 161. Saroglou H, Marinos P, Tsiambaos G (2004) The anisotropic nature of selected metamorphic rocks from Greece. S Afr Inst Min Metall 104:217–222
  • 162. Schoenberg M, Douma J (1988) Elastic wave propagation in media with parallel fractures and aligned cracks. Geophys Prospect 36:571–590
  • 163. Şengör AMC (1979a) Mid-Mesozoic closure of Permo-Triassic Tethys and its implications. Nature 279:590–593
  • 164. Şengör AMC (1979b) The north Anatolian transform fault: its age, offset and tectonic significance. J Geol Soc Lond 136:269–282
  • 165. Şengör AMC (1987) Tectonics of the Tethysides: orogenic collage development in a collisional setting. Annu Rev Earth Planet Sci 15:213–244
  • 166. Şengör AMC, Yılmaz Y (1981) Tethyan evolution of Turkey: a plate tectonic approach. Tectonophysics 75:181–241
  • 167. Şengör AMC, Satır M, Akkök R (1984) Timing of tectonic events in the Menderes Massif, Western Turkey: implications for tectonic evolution and evidence for Pan-African basement in Turkey. Tectonics 3:697–707
  • 168. Seyitoğlu G, Işık V, Çemen I (2004) Complete Tertiary exhumation history of the Menderes massif, western Turkey: an alternative working hypothesis. Terra Nova 16:358–364
  • 169. Shapiro NM, Ritzwoller MH (2002) Monte-Carlo inversion for a global shear-velocity model of the crust and upper mantle. Geophys J Int 151:88–105
  • 170. Shen W, Ritzwoller MH, Schulte-Pelkum V (2013) A 3-D model of the crust and uppermost mantle beneath the Central and Western US by joint inversion of receiver functions and surface wave dispersion. J Geophys Res Solid Earth 118:262–276. https://doi.org/10.1029/2012JB009602
  • 171. Soomro RA, Weidle C, Cristiano L, Lebedev S, Meier T, PASSEQ Working Group (2016) Phase velocities of Rayleigh and Love waves in central and northern Europe from automated, broad-band, interstation measurements. Geophys J Int 204:517–534
  • 172. Spica Z, Perton M, Legrand D (2017) Anatomy of the Colima volcano magmatic system, Mexico. Earth Planet Sci Lett 459:1–13
  • 173. Stampfli GM (2000) Tethyan oceans. In: Bozkurt E, Winchester JA, Piper JDA (eds) Tectonics and magmatism in Turkey and the surrounding area, vol 173. Geological Society of London (Special Publication), London, pp 1–23
  • 174. Tank SB, Özaydın S, Karaş M (2018) Revealing the electrical properties of a gneiss dome using three-dimensional magnetotellurics: burial and exhumation cycles associated with faulting in Central Anatolia, Turkey. Phys Earth Planet Inter 283:26–37
  • 175. Tarantola A (1987) Inverse problem theory. Elsevier Science Company Inc., Amsterdam, pp 187–255
  • 176. Tarantola A, Nercessian A (1984) Three-dimensional inversion without blocks. Geophys J R Astron Soc 76:299–306
  • 177. Taymaz T, Yılmaz Y, Dilek Y (eds) (2007) The geodynamics of the Aegean and Anatolia: introduction, vol 291. Geological Society of London (Special Publications), London, pp 1–16
  • 178. Tezel T, Erduran M, Alptekin Ö (2007) Crustal shear wave velocity structure of Turkey by surface wave dispersion analysis. Ann Geophys 50:177–190
  • 179. Thomson SN, Ring U (2006) Thermochronologic evaluation of postcollision extension in the Anatolide orogen, western Turkey. Tectonics 25:TC3005. https://doi.org/10.1029/2005TC001833
  • 180. Torsvik TH, Cocks LRM (2009) The Lower Palaeozoic palaeogeographical evolution of the northeastern and eastern peri-Gondwanan margin from Turkey to New Zealand. Geol Soc Lond Spec Publ 325:3–21
  • 181. Unsworth M (2010) Magnetotelluric studies of active continent–continent collisions. Surv Geophys 31:137–161
  • 182. van Hinsbergen DJJ (2010) A key extensional metamorphic complex reviewed and restored: the Menderes Massif of western Turkey. Earth Sci Rev 102:60–76
  • 183. van Hinsbergen DJJ, Kaymakci N, Spakman W, Torsvik TH (2010) Reconciling the geological history of western Turkey with plate circuits and mantle tomography. Earth Planet Sci Lett 297:674–686
  • 184. Vanacore EA, Taymaz T, Saygin E (2013) Moho structure of the Anatolian Plate from receiver function analysis. Geophys J Int 193:329–337
  • 185. Vernik L, Lockner D, Zoback MD (1992) Anisotropic strength of some typical metamorphic rocks from the KTB pilot hole, Germany. Sci Drill 3:153–160
  • 186. Vigneresse J-L, Tikoff B, Améglio L (1999) Modification of the regional stress field by magma intrusion and formation of tabular granitic plutons. Tectonophysics 302:203–224
  • 187. Visser K, Trampert J, Lebedev S, Kennett BLN (2008) Probability of radial anisotropy in the deep mantle. Earth Planet Sci Lett 270:241–250
  • 188. Waldron JWF (1984) Structural history of the Antalya Complex in the ‘Isparta angle’, Southwest Turkey. Geol Soc Lond Spec Publ 17:273–286
  • 189. Warren LM, Beck SL, Biryol CB, Zandt G, Özacar AA, Yang Y (2013) Crustal velocity structure of Central and Eastern Turkey from ambient noise tomography. Geophys J Int 194:1941–1954
  • 190. Whitney DL, Teyssier C, Kruckenberg SC, Morgan VL, Iredale LJ (2008) High pressure–low-temperature metamorphism of metasedimentary rocks, southern Menderes Massif, western Turkey. Lithos 101:218–232
  • 191. Yang Y, Forsyth DW (2006) Regional tomographic inversion of the amplitude and phase of Rayleigh waves with 2-D sensitivity kernels. Geophys J Int 166:1148–1160
  • 192. Yao H, Xu G, Zhu L, Xiao X (2005) Mantle structure from interstation Rayleigh wave dispersion and its tectonic implication in western China and neighboring regions. Phys Earth Planet Inter 148:39–54
  • 193. Yao H, Van der Hilst RD, De Hoop MV (2006) Surface-wave array tomography in SE Tibet from ambient seismic noise and two-station analysis—I. Phase velocity maps. Geophys J Int 166:732–744
  • 194. Yılmaz Y (1997) Geology of Western Anatolia. E.T.H. Univ. Press, Zurich. In: Schindler C, Fister MP (eds) Active tectonics of Northwestern Anatolia—the Marmara Poly-Project. Vdf Hochschulverlag AG an der ETH, Zürich, pp 31–53
  • 195. Yılmaz Y (2008) Main geological problems of Western Anatolia and the significance of the Bodrum magmatic province. IOP Conf Ser Earth Environ Sci. https://doi.org/10.1088/1755-1307/2/1/012007
  • 196. Yilmaz Y, Genç ŞC, Gürer F, Bozcu M, Yilmaz K, Karacik Z, Altunkaynak Ş, Elmas A (2000) When did the Western Anatolian grabens begin to develop? Geol Soc Lond Spec Publ 173:353–384
  • 197. Yolsal-Çevikbilen S, Taymaz T, Helvacı C (2014) Earthquake mechanisms in the Gulfs of Gökova, Sığacık, Kuşadası, and the Simav Region (western Turkey): neotectonics, seismotectonics and geodynamic implications. Tectonophysics 635:100–124
  • 198. Yoshizawa K, Kennett BLN (2002) Determination of the influence zone for surface wave paths. Geophys J Int 149:440–453
  • 199. Yoshizawa K, Kennett BLN (2004) Multimode surface wave tomography for the Australian region using a three-stage approach incorporating finite frequency effects. J Geophys Res 109:B02310. https://doi.org/10.1029/2002JB002254
  • 200. Yoshizawa K, Miyake K, Yomogida K (2010) 3D upper mantle structure beneath Japan and its surrounding region from inter-station dispersion measurements of surface waves. Phys Earth Planet Inter 183:4–19
  • 201. Zhang S, Karato S (1995) Lattice preferred orientation of olivine deformed in simple shear. Nature 375:774–777. https://doi.org/10.1038/375774a0
  • 202. Zor E, Sandvol E, Gürbüz C, Türkelli N, Seber D, Barazangi M (2003) The crustal structure of the East Anatolian plateau (Turkey) from receiver functions. Geophys Res Lett 30:8044. https://doi.org/10.1029/2003GL018192
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e16e1b38-225a-4b54-bf03-bbe2742fb2ab
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