Lessons learned from marine refraction seismic experiments in the Ligurian Sea

Open Access

Numéro		BSGF - Earth Sci. Bull. Volume 196, 2025


Numéro d'article		21
Nombre de pages		18
DOI		https://doi.org/10.1051/bsgf/2025009
Publié en ligne		5 novembre 2025

Afilhado A. et al. 2008. From Unthinned continent to ocean: the deep structure of the west iberia passive continental margin at 38°N. Tectonophysics 458: 9–50. [Google Scholar]
Afilhado A et al. 2015. Deep crustal structure across a young passive margin from wide-angle and reflection seismic data (The SARDINIA Experiment) − II. Sardinia’s margin. Bull Société Géologique de France 186: 331–351. [Google Scholar]
Alaei B. 2012. Seismic Modeling of Complex Geological Structures. Seismic Waves − Research and Analysis. Ed. by Masaki Kanao. InTech. https://doi.org/10.5772/29423. (Visited on 10/21/2024) [Google Scholar]
Aslanian D, Olivet JL. 2006. SARDINIA Cruise Report RV L’Atalante. Tech. rep. France: Ifremer. [Google Scholar]
Bache F et al. 2009. Messinian Erosional and Salinity Crises: View from the Provence Basin (Gulf of Lions, Western Mediterranean). Earth and Planetary Science Letters 286: 139–157. [Google Scholar]
Bache F et al. 2015. Messinian evaporite deposition during sea level rise in the gulf of lions (Western Mediterranean). Marine and Petroleum Geology 66: 262–277. [Google Scholar]
Bellucci M et al. 2024. Salt tectonics evolution in the Provençal Basin, Western Mediterranean Sea. BSGF − Earth Sci Bull 195: 16. [Google Scholar]
Béthoux N et al. 2008. Why Is the Ligurian Basin (Mediterranean Sea) Seismogenic? thermomechanical modeling of a reactivated passive margin. Tectonics 27: 16. [Google Scholar]
Boschetti L. et al. 2023. A New Tomographic-Petrological Model for the Ligurian-Provence Back-Arc Basin (North-Western Mediterranean Sea). Tectonophysics 868: 230111. [Google Scholar]
Cohen JK, Stockwell JW Jr. 2002. CWP/SU: Seismic Un*x Release No. __: An Open Source Software Package for Seismic Research and Processing. Center for Wave Phenomena, Colorado School of Mines. Colorado, USA. [Google Scholar]
Contrucci I. et al. 2001. A Ligurian (Western Mediterranean Sea) geophysical transect revisited. Geophys J Int 146: 74–97. [Google Scholar]
Crawford W. 2017. AlpArray Leg1 Cruise Report, R/V Pourquoi Pas? https://doi.org/10.17600/17000400. (Visited on 11/12/2024) [Google Scholar]
Dannowski A, Kopp H, Lange D. 2020a. seismic refraction and wide-angle reflection data from profile MSM71-P02 of Maria S. Merian Cruise MSM71 in the Ligurian Basin, with Links to SGY Data Files. https://doi.org/10.1594/PANGAEA.910561 [Google Scholar]
Dannowski A et al. 2020b. Seismic evidence for failed rifting in the Ligurian Basin, Western Alpine Domain. Solid Earth 11: 873–887. [Google Scholar]
Dessa J-X et al. 2011. The GROSMarin experiment: three dimensional crustal structure of the North Ligurian margin from refraction tomography and preliminary analysis of microseismic measurements. Bull Société Géologique de France 182: 305–321. [Google Scholar]
Dessa J-X et al. 2020. Seismic exploration of the deep structure and seismogenic faults in the Ligurian sea by joint multi channel and ocean bottom seismic acquisitions: preliminary results of the SEFASILS Cruise. Geosciences 10: 108. [Google Scholar]
Dunn RA, Toomey DR, Solomon SC. 2000. Three-dimensional Seismic Structure and Physical Properties of the Crust and Shallow Mantle beneath the East Pacific Rise at 9∘30’N. J Geophys Res: Solid Earth 105: 23537–23555. [Google Scholar]
Fujie G et al. 2008. Interactive analysis tools for the wide-angle seismic data for crustal structure study (technical report). Explor Geophys 39: 26–33. [Google Scholar]
Gailler A. et al. 2009. Crustal structure of a young margin pair: new results across the liguro-provencal basin from wide-angle seismic tomography. Earth Planet Sci Lett 286: 333–345. [Google Scholar]
García M et al. 2011. The Catalan Margin during the Messinian Salinity Crisis: Physiography, Morphology and Sedimentary Record. Marine Geology 284: 158–174. [Google Scholar]
Górszczyk A, Brossier R, Métivier L. 2024. On the effect of 3D wave propagation on 2D regional-scale velocity model building. J Geophys Res: Solid Earth 129: e2023JB028172. [Google Scholar]
Górszczyk A, Operto S. 2021. GO_3D_OBS: TheMulti-Parameter Benchmark Geomodel for Seismic Imaging Method Assessment and next-Generation 3D Survey Design (Version 1.0). Geosci Model Dev 14: 1773–1799. [Google Scholar]
Gueguen E, Doglioni C, Fernandez M. 1998. On the Post-25 Ma geodynamic evolution of the Western Mediterranean. Tectonophysics 298: 259–269. [CrossRef] [Google Scholar]
Hovland V. 2016. Transforming ocean bottom seismic technology into an exploration tool. First Break 34: 1365–2397. [Google Scholar]
Jolivet L, Faccenna C. 2000. Mediterranean Extension and the Africa-Eurasia Collision. Tectonics 19: 1095–1106. [CrossRef] [Google Scholar]
Jolivet L et al. 2006. Lithospheric-Scale Geodynamic Context of the Messinian Salinity Crisis. Sedimentary Geology 188-189: 9–33. [CrossRef] [Google Scholar]
Jones IF, Davison I. 2014. Seismic Imaging in and around Salt Bodies. Interpretation 2: SL1–SL20. [Google Scholar]
Khan S et al. 2020. The impact of topography on seismic amplification during the 2005 Kashmir earthquake. Natural Hazards Earth System Sci 20: 399–411. [Google Scholar]
Kopp H et al. 2018. Cruise Report MSM71 LOBSTER: Ligurian Ocean Bottom Seismology and Tectonics Research, Las Palmas (Spain) − Heraklion (Greece). Tech. rep. 041. Kiel, Germany: GEOMAR Helmholtz-Zentrum für Ozeanforschung Kiel, p. 47. [Google Scholar]
Larroque C, de Lépinay BM, Migeon S. 2011. Morphotectonic and Fault-Earthquake Relationships along the Northern Ligurian Margin (Western Mediterranean) Based on High Resolution, Multibeam Bathymetry and Multichannel Seismic-Reflection Profiles. Marine Geophysical Research 32: 163–179. [Google Scholar]
Lefeldt M, Ranero CR, Grevemeyer I. 2012. Seismic evidence of tectonic control on the depth of water influx into incoming oceanic plates at subduction trenches. Geochem Geophys Geosyst 13: Q05013. [Google Scholar]
Lefeldt M. et al. 2009. Intraplate Seismicity and Related Mantle Hydration at the Nicaraguan Trench Outer Rise. Geophys J Int 178: 742–752. [Google Scholar]
Maillard and Mauffret. 1999. Crustal Structure and Riftogenesis of the Valencia Trough (North-Western Mediterranean Sea): The Valencia Trough, NW Mediterranean. Basin Res 11: 357–379. [CrossRef] [Google Scholar]
Marjanović M et al. 2019. Elastic versus Acoustic 3-D Full Waveform Inversion at the East Pacific Rise 9^∘50′N. Geophys J Int 216: 1497–1506. [Google Scholar]
McNutt SR. 2005. Volcanic Seismology. Annu Rev Earth Planet Sci 33: 461–491. [Google Scholar]
Meléndez A. et al. 2015. TOMO3D: 3-D joint refraction and reflection travel time tomography parallel code for active-source seismic data—synthetic test. Geophys J Int 203: 158–174. [Google Scholar]
Meléndez A et al. 2014. Origin of water layer multiple phases with anomalously high amplitude in near-seafloor wide-angle seismic recordings. Geophys J Int 196: 243–252. [Google Scholar]
Merino I et al. 2021. The structure of the continent-ocean transition in the gulf of lions from joint refraction and reflection travel-time tomography. J Geophys Res: Solid Earth 126: 1–20. [Google Scholar]
Morgan J. et al. 2013. Next-Generation Seismic Experiments:Wide-Angle, Multi-Azimuth, Three-Dimensional, Full-Waveform Inversion. Geophys J Int 195: 1657–1678. [Google Scholar]
Moulin M et al. 2015. Deep crustal structure across a young passive margin from wide-angle and reflection seismic data (The SARDINIA Experiment)- I. Gulf of Lion’s Margin. Bulletin de La Société Géologique de France 186: 309–330. [Google Scholar]
Nocquet J-M., Calais E. 2004. Geodetic Measurements of Crustal Deformation in the Western Mediterranean and Europe. Pure Appl Geophys 161: 661–681. [CrossRef] [Google Scholar]
Pautot G et al. 1984. Morphology and extension of the evaporitic structures of the Liguro-Provincal Basin: New SEA-BEAM Data. Mar Geol 55: 387–409. [CrossRef] [Google Scholar]
Peirce C et al. 2022. Three-Dimensional S −Wave Velocity Structure of Oceanic Core Complexes at 13∘N on the Mid-Atlantic Ridge. Geophys J Int 232: 615–642. [Google Scholar]
Pipatprathanporn S and Simons FJ. 2021. One year of sound recorded by a mermaid float in the pacific: hydroacoustic earthquake signals and infrasonic ambient noise. Geophys J Int 228: 193–212 [Google Scholar]
Rawlinson N. 2007. FMTOMO-Fast Marching Tomography Package: Instruction Manual. [Google Scholar]
Rawlinson N, de Kool M, Sambridge M. 2006. Seismic wavefront tracking in3D heterogeneous media: applications with multiple data classes. Explor Geophys 37: 322–330. [Google Scholar]
Rehault J-P., Boillot G, Mauffret A. 1984. The Western mediterranean basin geological evolution. Mar Geol 55: 447–477. [CrossRef] [Google Scholar]
Réhault J-P et al. 2012. Offshore Oligo-Miocene volcanic fields within the Corsica-Liguria basin: magmatic diversity and slab evolution in the Western Mediterranean Sea. J Geodyn 58: 73–95. [Google Scholar]
Rollet N et al. 2002. Back Arc Extension, Tectonic Inheritance, and Volcanism in the Ligurian Sea, Western Mediterranean: LIGURIAN SEA BACK ARC STRUCTURE AND EVOLUTION. Tectonics 21: 6–1–6–23. [Google Scholar]
Rowe CA et al. 2022. Editorial: advances in ocean bottom seismology. Front Earth Sci 10: 852059. [Google Scholar]
Sambolian S et al. 2021. Mitigating the Ill-Posedness of First-Arrival Traveltime Tomography Using Slopes: application to the Eastern Nankai Trough (Japan) OBS Data Set. Geophys J Int 227: 898–921. [Google Scholar]
Schettino A, Turco E. 2006. Plate Kinematics of the Western Mediterranean Region during the Oligocene and Early Miocene. Geophys J Int 166: 1398–1423. [CrossRef] [Google Scholar]
Schultz-Ela DD, Jackson MPA, Vendeville BC. 1993. Mechanics of Active Salt Diapirism. Tectonophysics 228: 275–312. [Google Scholar]
Simão NM et al. 2020. 3-D P-wave velocity structure of oceanic core complexes at 13∘N on the Mid-Atlantic Ridge. Geophys J Int 221: 1555–1579. [Google Scholar]
Simmons NA et al. 2019. Resolution and covariance of the LLNL-G3D-JPS global seismic tomography model: applications to travel time uncertainty and tomographic filtering of geodynamic models. Geophys J Int 217: 1543–1557. [Google Scholar]
Thorwart M et al. 2021. Basin Inversion: Reactivated Rift Structures in the Central Ligurian Sea Revealed Using Ocean Bottom Seismometers. Solid Earth 12: 2553–2571. [Google Scholar]
Tong CH et al. 2003. Influence of enhanced melt supply on upper crustal structure at a mid-ocean ridge discontinuity: a three-dimensional seismic tomographic study of 9^∘ N East Pacific Rise. J Geophys Res: Solid Earth 108: B10. [Google Scholar]
Toomey DR, Foulger GR. 1989. Tomographic inversion of local earthquake data from the Hengill-Grensdalur Central Volcano Complex, Iceland. J Geophys Res: Solid Earth 94: 17497–17510. [Google Scholar]
Vermeer GJO. 2012. Chapter 2: 3D Acquisition Geometries, Their Properties, and Their Sampling and Chapter 5: Marine Seismic Data Acquisition. 3D Seismic Survey Design, Second Edition. Society of Exploration Geophysicists. [Google Scholar]
Vigliotti L, Langenheim VE. 1995. When did Sardinia stop rotating? New Palaeomagnetic Results. Terra Nova 7: 424–435. [Google Scholar]
Widess MB. 1973. How thin is a thin bed. Geophysics 38: 1176–1180. [Google Scholar]
Zelt CA. 1999. Modelling strategies and model assessment for wide-angle seismic traveltime data. Geophys J Int 139: 183–204. [Google Scholar]
Zelt CA, Smith RB. 1992. Seismic traveltime inversion for 2-D crustal velocity structure. Geophys J Int 108: 16–34. [Google Scholar]
Zelt CA. 1998. Lateral velocity resolution from three-dimensional seismic refraction data. Geophys J Int 135: 1101–1112. [Google Scholar]

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