Comment on “Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section” by Pedrera et al.
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[1] Y. Lagabrielle,et al. Crustal structure and evolution of the Pyrenean-Cantabrian belt: A review and new interpretations from recent concepts and data , 2018 .
[2] J. Vergés,et al. A New Southern North Atlantic Isochron Map: Insights Into the Drift of the Iberian Plate Since the Late Cretaceous , 2017 .
[3] A. Pedrera,et al. Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section , 2017 .
[4] E. Iriarte,et al. Mantle exhumation and metamorphism in the Basque‐Cantabrian Basin (N Spain): Stable and clumped isotope analysis in carbonates and comparison with ophicalcites in the North‐Pyrenean Zone (Urdach and Lherz) , 2017 .
[5] J. Díaz,et al. Moho topography beneath the Iberian-Western Mediterranean region mapped from controlled-source and natural seismicity surveys , 2016 .
[6] D. Komatitsch,et al. The deep roots of the western Pyrenees revealed by full waveform inversion of teleseismic P waves , 2016 .
[7] Y. Lagabrielle,et al. The crustal evolution of the west-central Pyrenees revisited: Inferences from a new kinematic scenario , 2016 .
[8] J. Díaz,et al. High resolution Moho topography map beneath Iberia and Northern Morocco from receiver function analysis , 2015 .
[9] J. A. Pulgar,et al. Displacement transfer from borders to interior of a plate: A crustal transect of Iberia , 2015 .
[10] J. Vergés,et al. Crust and mantle lithospheric structure of the Iberian Peninsula deduced from potential field modeling and thermal analysis , 2015 .
[11] D. García-Castellanos,et al. Geophysical-petrological modeling of the lithosphere beneath the Cantabrian Mountains and the North-Iberian margin: geodynamic implications , 2015 .
[12] Pieter Vermeesch,et al. Thermal history modelling: HeFTy vs. QTQt , 2014 .
[13] I. Thinon,et al. Formation and deformation of hyperextended rift systems: Insights from rift domain mapping in the Bay of Biscay‐Pyrenees , 2014 .
[14] E. Masini,et al. The tectono-sedimentary evolution of a hyper-extended rift basin: the example of the Arzacq–Mauléon rift system (Western Pyrenees, SW France) , 2014, International Journal of Earth Sciences.
[15] D. Pedreira,et al. Mapping the indentation between the Iberian and Eurasian plates beneath the Western Pyrenees/Eastern Cantabrian Mountains from receiver function analysis , 2012 .
[16] R. Vissers,et al. Iberian plate kinematics and Alpine collision in the Pyrenees , 2012 .
[17] J. Muñoz,et al. The role of the Bay of Biscay Mesozoic extensional structure in the configuration of the Pyrenean orogen: Constraints from the MARCONI deep seismic reflection survey , 2011 .
[18] Y. Lagabrielle,et al. Mantle exhumation, crustal denudation, and gravity tectonics during Cretaceous rifting in the Pyrenean realm (SW Europe): Insights from the geological setting of the lherzolite bodies , 2010 .
[19] L. Lavier,et al. Tectonosedimentary evolution related to extreme crustal thinning ahead of a propagating ocean: Example of the western Pyrenees , 2009 .
[20] J. Díaz,et al. Crustal structure beneath the Iberian Peninsula and surrounding waters: A new compilation of deep seismic sounding results , 2009 .
[21] A. S. Fokas,et al. A unified approach to various techniques for the non-uniqueness of the inverse gravimetric problem and wavelet-based methods , 2008 .
[22] Y. Lagabrielle,et al. Submarine reworking of exhumed subcontinental mantle rocks: field evidence from the Lherz peridotites, French Pyrenees , 2008 .
[23] D. Pedreira,et al. Three‐dimensional gravity and magnetic modeling of crustal indentation and wedging in the western Pyrenees‐Cantabrian Mountains , 2007 .
[24] J. Uriarte,et al. Thermal models and clay diagenesis in the Tertiary-Cretaceous sediments of the Alava block (Basque-Cantabrian basin, Spain) , 2006, Clay Minerals.
[25] H. Paulick,et al. Unraveling the sequence of serpentinization reactions: petrography, mineral chemistry, and petrophysics of serpentinites from MAR 15°N (ODP Leg 209, Site 1274) , 2006 .
[26] P. Crill,et al. Constraining the rate and extent of mantle serpentinization from seismic and petrological data: implications for chemosynthesis and tectonic processes , 2005 .
[27] N. Christensen,et al. Serpentinites, Peridotites, and Seismology , 2004 .
[28] C. Mével. Serpentinization of abyssal peridotites at mid-ocean ridges , 2003 .
[29] D. Pedreira,et al. Teleseismic imaging of alpine crustal underthrusting beneath Niberia , 2003 .
[30] D. Pedreira,et al. Seismic evidence of Alpine crustal thickening and wedging from the western Pyrenees to the Cantabrian Mountains (north Iberia) , 2003 .
[31] D. Miller,et al. Mantle wedge water contents estimated from seismic velocities in partially serpentinized peridotites , 2003 .
[32] G. Lister,et al. Relative motions of Africa, Iberia and Europe during Alpine orogeny , 2002 .
[33] J. Vergés,et al. Inversion tectonics of the northern margin of the Basque Cantabrian Basin , 2002 .
[34] M. Cannat,et al. Magnetic properties of variably serpentinized abyssal peridotites , 2002 .
[35] B. Evans,et al. Strength of slightly serpentinized peridotites: Implications for the tectonics of oceanic lithosphere , 2001 .
[36] A. Teixell. Crustal structure and orogenic material budget in the west central Pyrenees , 1998 .
[37] R. Rudnick,et al. Nature and composition of the continental crust: A lower crustal perspective , 1995 .
[38] Richard A. Ketcham,et al. Comment on “Thermal history modelling: HeFTy vs. QTQt” by Vermeesch and Tian, Earth-Science Reviews (2014), 139, 279–290 , 2018 .
[39] J. Muñoz. Evolution of a continental collision belt: ECORS-Pyrenees crustal balanced cross-section , 1992 .