Nature of the lithosphere across the Variscan orogen of SW Iberia: Dense wide‐angle seismic reflection data

[1] Two wide-angle seismic transects have been acquired across the SW Iberian Massif. They crossed three major geological zones (South Portuguese Zone, Ossa-Morena Zone, and Central Iberian Zone), with their tectonic contacts and the Pyrite Belt being of greatest interest. A total of 690 digital seismic recording instruments (650 Texans and 40 Reftek 3 component units) from the IRIS-PASSCAL Instrument Pool were used. The transects (A and B) are each approximately 300 km long and consist of 3 and 6 shot points, respectively, with an approximately 60-km shot point interval. The charge sizes range from 1000 kg at the edges to 500 kg at the center. These recently acquired experiments were designed to provide velocity constraints on the lithosphere and to complement the previously acquired normal incidence seismic profile IBERSEIS. Both data sets are part of the SW Iberia project, which was developed within the EUROPROBE program and designed to address fundamental questions about the nature and dynamics of the Variscan lithosphere. The acquisition parameters provide closely spaced wide-angle seismic images of the lithosphere beneath SW Iberia. In transect A, the station spacing was on average 400 m, while along transect B, the receiver spacing was approximately 150 m. Because of this close trace spacing, the lateral continuity of the seismic arrivals is greatly improved. Frequency analysis revealed that the recorded events feature relatively low frequencies (6–25 Hz). After processing, the shot records show high-amplitude and well-defined arrivals. The interpreted PmP arrival, located at approximately 11 s (normal incidence traveltime), is characterized by high amplitude and relatively low frequency (6–12 Hz). A well-defined Pn arrival appears at offsets beyond 120 km. At far offsets greater than 180 km, an upper mantle reflection is observed. Furthermore, within the upper crust, the shots records feature a relatively high-velocity arrival, located at 4–5-s normal incidence traveltime. The analysis of this arrival indicates that it probably corresponds to the top of the Iberian Reflective Body identified in the IBERSEIS deep seismic profile. The velocity models obtained by forward modeling show a complex crust, especially in the middle crust. The velocity models are the most detailed ones that have been produced in the area and contain a large amount of new features that are relevant to the understanding of the composition of the crust and upper mantle beneath the zone. The velocity depth functions derived from the velocity models have higher middle crustal velocities than the average in other continental areas. A comparison between laboratory seismic velocity measurements and the velocities of the models was carried out in order to estimate the crustal and the upper mantle composition. Results indicate that the high middle crust velocities correspond to rocks of a mafic composition. The combined data set reveals new aspects related to the lithospheric evolution of this transpressive orogen and allows us to attempt an interpretative cross section of the upper lithosphere in SW Iberia.

[1]  Á. Marcuello,et al.  Magnetotelluric survey of the electrical conductivity of the crust across the Ossa Morena Zone and South Portuguese Zone suture , 1999 .

[2]  A. Mateus,et al.  Are some of the deep crustal conductive features found in SW Iberia caused by graphite , 2002 .

[3]  P. Matte Tectonics and plate tectonics model for the Variscan belt of Europe , 1986 .

[4]  M. Orozco,et al.  The southern Iberian shear zone: a major boundary in the Hercynian folded belt , 1988 .

[5]  P. Kelemen,et al.  The role of H2O during crystallization of primitive arc magmas under uppermost mantle conditions and genesis of igneous pyroxenites: an experimental study , 2001 .

[6]  P. Kelemen,et al.  Along‐Strike Variation in the Aleutian Island Arc: Genesis of High Mg# Andesite and Implications for Continental Crust , 2013 .

[7]  I. Kukkonen,et al.  Composition of the Uralide crust from seismic velocity ( V p , V s ), heat flow, gravity, and magnetic data , 2003 .

[8]  P. Kelemen,et al.  One View of the Geochemistry of Subduction-Related Magmatic Arcs, with an Emphasis on Primitive Andesite and Lower Crust , 2005 .

[9]  Obata Masaaki The Ronda Peridotite: Garnet-, Spinel-, and Plagioclase-Lherzolite Facies and the P-T Trajectories of a High-Temprature Mantle Intrusion , 1980 .

[10]  H. Kern,et al.  Petrophysical studies on rocks from the Dabie ultrahigh-pressure (UHP) metamorphic belt , 1999 .

[11]  R. Kay,et al.  Ultramafic and Mafic Inclusions from Adak Island: Crystallization History, and Implications for the Nature of Primary Magmas and Crustal Evolution in the Aleutian Arc , 1984 .

[12]  Friedemann Wenzel,et al.  Seismic wide-angle constraints on the crust of the southern Urals , 2000 .

[13]  J. Burg,et al.  Variscan intracontinental deformation: The Coimbra—Cordoba shear zone (SW Iberian Peninsula) , 1981 .

[14]  E. Pascual,et al.  Magmatism in the Iberian Pyrite Belt: petrological constraints on a metallogenic model , 1997 .

[15]  J. Melgarejo,et al.  Electromagnetic imaging of Variscan crustal structures in SW Iberia: the role of interconnected graphite , 2004 .

[16]  R. D. Dallmeyer,et al.  Pre-Mesozoic Geology of Iberia , 1991 .

[17]  A. Plesch,et al.  Passive margin detachment during arc-continent collision (Central European Variscides) , 2000, Geological Society, London, Special Publications.

[18]  R. Arculus,et al.  Laboratory wave velocity measurements on lower crustal xenoliths from Calcutteroo, South Australia , 1984 .

[19]  A. Azor,et al.  Tectonic evolution of the boundary between the Central Iberian and Ossa‐Morena zones (Variscan belt, southwest Spain) , 1994 .

[20]  H. Kern The effect of high temperature and high confining pressure on compressional wave velocities in quartz-bearing and quartz-free igneous and metamorphic rocks , 1978 .

[21]  A. Azor,et al.  The structure of a major suture zone in the SW Iberian Massif: the Ossa-Morena/Central Iberian contact , 2001 .

[22]  J. M. Fernández-Soler,et al.  The amphibolites from the Ossa Morena/Central Iberian Variscan suture (Southwestern Iberian Massif): geochemistry and tectonic interpretation , 2003 .

[23]  G. Rogers,et al.  Significance of MORB-derived Amphibolites from the Aracena Metamorphic Belt, Southwest Spain , 1996 .

[24]  J. Gallart,et al.  Modelling and imaging the Moho transition: the case of the southern Urals , 2002 .

[25]  R. Carbonell On the nature of mantle heterogeneities and discontinuities: evidence from a very dense wide-angle shot record , 2004 .

[26]  N. Christensen,et al.  Seismic anisotropy in the oceanic upper mantle: Evidence from the Bay of Islands Ophiolite Complex , 1979 .

[27]  S. Kay,et al.  Ultramafic Xenoliths from Adagdak Volcano, Adak, Aleutian Islands, Alaska: Deformed Igneous Cumulates from the Moho of an Island Arc , 1987, The Journal of Geology.

[28]  A. Pérez-Estaún,et al.  Crustal thickening and deformation sequence in the footwall to the suture of the Variscan belt of northwest Spain , 1991 .

[29]  H. Kern,et al.  Measured and calculated seismic velocities and densities for granulites from xenolith occurrences and adjacent exposed lower crustal sections: A comparative study from the North China craton , 2000 .

[30]  F. Velasco,et al.  Erratum to A new style of Ni-Cu mineralization related to magmatic breccia pipes in a transpressional magmatic arc, Aguablanca, Spain , 2001 .

[31]  M. Manghnani,et al.  Compressional and shear wave velocities in granulite facies rocks and eclogites to 10 kbar , 1974 .

[32]  O. Oncken,et al.  Orogenic Evolution of the Ural Mountains: Results from an Integrated Seismic Experiment , 1996, Science.

[33]  F. Tornos,et al.  A new scenario for related IOCG and Ni–(Cu) mineralization: the relationship with giant mid‐crustal mafic sills, Variscan Iberian Massif , 2005 .

[34]  N. Christensen Compressional wave velocities in metamorphic rocks at pressures to 10 kilobars , 1965 .

[35]  J. M. Fernández-Soler,et al.  Phase diagram sections applied to amphibolites: a case study from the Ossa-Morena/Central Iberian Variscan suture (Southwestern Iberian Massif) , 2003 .

[36]  D. Eaton Multi‐genetic origin of the continental Moho: insights from Lithoprobe , 2006 .

[37]  H. Downes Shallow continental lithospheric mantle heterogeneity - Petrological constraints , 1997 .

[38]  J. Gallart,et al.  Crustal Root Beneath the Urals: Wide-Angle Seismic Evidence , 1996, Science.

[39]  F. Santos,et al.  New magnetotelluric data through the boundary between the Ossa Morena and Centroiberian Zones , 2005 .

[40]  C. Pin,et al.  Late Neoproterozoic crustal growth in the European Variscides: Nd isotope and geochemical evidence from the Sierra de Córdoba Andesites (Ossa-Morena Zone, Southern Spain) , 2002 .

[41]  D. Eaton,et al.  Lithospheric anisotropy structure inferred from collocated teleseismic and magnetotelluric observations: Great Slave Lake shear zone, northern Canada , 2004 .

[42]  F. M. Monteiro Santos,et al.  Magnetotelluric measurements in SW Iberia: New data for the Variscan crustal structures , 2005 .

[43]  J. Bard Signification tectonique des metatholeites d'affinite abyssale de la ceinture metamorphique de basse pression d'Aracena (Huelva, Espagne) , 1977 .

[44]  A. Lachenbruch,et al.  9: Models of an extending lithosphere and heat flow in the Basin and Range province , 1978 .

[45]  F. Simancas,et al.  Seismic imaging and modelling of the lithosphere of SW-Iberia , 2009 .

[46]  F. Velasco,et al.  The Aguablanca Cu–Ni ore deposit (Extremadura, Spain), a case of synorogenic orthomagmatic mineralization: age and isotope composition of magmas (Sr, Nd) and ore (S) , 2001 .

[47]  C. Juhlin,et al.  Transpressional collision tectonics and mantle plume dynamics: the Variscides of southwestern Iberia , 2006, Geological Society, London, Memoirs.

[48]  N. Christensen,et al.  Velocities of southern Basin and Range xenoliths: Insights on the nature of lower crustal reflectivity and composition , 1995 .

[49]  J. Pedro,et al.  VARISCAN OPHIOLITES AND HIGH-PRESSURE METAMORPHISM IN SOUTHERN IBERIA , 1999 .

[50]  D. Miller,et al.  Seismic signature and geochemistry of an island arc: A multidisciplinary study of the Kohistan accreted terrane, northern Pakistan , 1994 .

[51]  S. Smithson,et al.  Processing and inversion of refraction and wide‐angle reflection data from the 1986 Nevada Passcal Experiment , 1990 .

[52]  Robert B. Smith,et al.  Seismic traveltime inversion for 2-D crustal velocity structure , 1992 .

[53]  R. E. Long,et al.  The nature of crustal boundaries: combined interpretation of wide-angle and normal-incidence seismic data , 1994 .

[54]  D. Fountain The Ivrea—Verbano and Strona-Ceneri Zones, Northern Italy: A cross-section of the continental crust—New evidence from seismic velocities of rock samples , 1976 .

[55]  J. A. Pulgar,et al.  Estudio Sísmico de la Corteza Ibérica Norte 3.3: A seismic image of the Variscan crust in the hinterland of the NW Iberian Massif , 1998 .

[56]  J. W. Spencer,et al.  The effects of pressure, temperature, and pore water on velocities in Westerly granite. [for seismic wave propagation , 1976 .

[57]  P. Fonseca,et al.  Tectonics of the Beja-Acebuches Ophiolite: a major suture in the Iberian Variscan Foldbelt , 1993 .

[58]  F. Birch The velocity of compressional waves in rocks to 10 kilobars: 1. , 1960 .

[59]  P. Kelemen,et al.  Composition and structure of the central Aleutian island arc from arc‐parallel wide‐angle seismic data , 2004 .

[60]  B. Ábalos,et al.  Cadomian subduction/collision and Variscan transpression in the Badajoz-Córdoba shear belt, southwest Spain , 1991 .

[61]  Z. Hajnal,et al.  Introduction to special issue of Canadian Journal of Earth Sciences: The Trans-Hudson Orogen Transect of Lithoprobe, , 2005 .

[62]  Y. S. Touloukian,et al.  Physical Properties of Rocks and Minerals , 1981 .

[63]  Walter D. Mooney,et al.  Seismic velocity structure and composition of the continental crust: A global view , 1995 .

[64]  J. Díaz,et al.  Evidence for azimuthal anisotropy in southwest Iberia from deep seismic sounding data , 1993 .

[65]  Á. Marcuello,et al.  Electromagnetic imaging of a transpressional tectonics in SW Iberia , 2001 .

[66]  W. Griffin,et al.  The composition and origin of sub-continental lithospheric mantle , 1999 .

[67]  M. Torné,et al.  Lithospheric transition from the Variscan Iberian Massif to the Jurassic oceanic crust of the Central Atlantic , 2004 .

[68]  N. White,et al.  PrefaceGeodynamics and ore deposit evolution in Europe , 2005 .

[69]  Christopher Juhlin,et al.  Crustal structure of the transpressional Variscan orogen of SW Iberia: SW Iberia deep seismic reflection profile (IBERSEIS) , 2003 .

[70]  J. Gallart,et al.  Mapping the Moho beneath the Southern Urals with wide‐angle reflections , 1998 .

[71]  R. Sáez,et al.  The Iberian type of volcano-sedimentary massive sulphide deposits , 1999 .

[72]  C. Evans,et al.  Seismic velocities of granulites from the Seiland Petrographic Province (N. Norway): Implications for Scandinavian lower continental crust , 1983 .

[73]  R. Rudnick,et al.  Nature and composition of the continental crust: A lower crustal perspective , 1995 .

[74]  B. O. Casado Geochronological studies of the pre-Mesozoic basement of the Iberian Massif : the Ossa Morena zone and the Allochthonous Complexes within the Central Iberian zone , 1998 .

[75]  F. Simancas,et al.  Geophysical evidence of a mantle derived intrusion in SW Iberia , 2004 .

[76]  N. Christensen,et al.  Constitution of the Lower Continental Crust Based on Experimental Studies of Seismic Velocities in Granulite , 1975 .

[77]  K. Furlong,et al.  Continental crustal underplating: Thermal considerations and seismic‐petrologic consequences , 1986 .