Structure type | Evaporite Diapir |
Deformed/Undeformed | Deformed |
Geological Setting | Basque Arc, Basque-Cantabrian Basin |
Outcropping/buried | Outcropping |
Evaporite unit/s name | Keuper facies |
Evaporite unit/s age | Carnian-Rhaetian (Upper Triassic) |
Evaporite unit/s origin | Marine |
Classif. (Hudec and Jackson, 2009) | Thrust piercement |
Classif. (Jackson and Talbot, 1986) | Salt wall |
Age of evaporite flow or deformation (when deformed) | Upper Jurassic to Upper Cretaceous |
Other comments | Salt motion lasted until syn-orogenic times, as the Maastrichtian layers are also affected by diapirs (see Ducoux et al., 2020). Complex tectonic structure. |
Unique ID | 40 |
Name | Uitzi |
Structure type | Evaporite diapir |
Deformed/Undeformed | Deformed |
Buried/Outcropping | Outcropping |
Geological setting | Basque-Cantabrian Basin |
Geological Regional Setting | Basque Arc |
Evaporite unit/s name | Keuper facies |
Evaporite unit/s age | Carnian-Rhaetian (Upper Triassic) |
Evaporite unit/s era | Mesozoic |
Evaporite unit/s origin | Marine |
Evaporite unit/s composition | Gypsum-Halite-Anhydrite-Claystone |
Post-kinematic unit/s (or post-evaporite units when evaporites are undeformed) | Quaternary (alluvial and colluvial detrital deposits) |
Post-kinematic unit/s age (or post-evaporite units when evaporites are undeformed) | Pleistocene-Holocene |
Classification (Hudec and Jackson, 2009) | Thrust piercement |
Classification (Jackson and Talbot, 1986) | Salt wall |
Mining activity? | Y |
Mining activity start | 19th century |
Mining activity end | 1950 |
Mining galleries? | Y |
Mining products | Pb-Zn |
Mining sub-products | – |
Evaporite flow? | Y |
Age of evaporite flow | Late Jurassic – Maastrichtian |
Flow or deformation triggering mechanisms | Mesozoic extensional regime in the Basque–Cantabrian Basin (Lowe Cretaceous, listric faults and salt tectonics) followed by Iberian plate drifting and tectonic inversion (Upper Cretaceous) |
Flow-linked structures? | Y |
Halokinetic structures | Normal high-angle faults / joints / thickness variations / progressive unconformities |
Post-evaporite and pre-kinematic unit/s (overbuden) | Jurassic (limestones, dolostones, oolitic limestones, marls) |
Syn-kinematic unit/s | Valanginian – Barremian (Weald facies, limestones, clays and sandstones) / Aptian – Albian (limestones, marls, sandstones and lutites) / Cenomanian – Maastrichtian (shales, marls and limestones) |
Available seismic profiles | 21 |
Available boreholes | |
Additional comments | Salt motion lasted until syn-orogenic times, as the Maastrichtian layers are also affected by diapirs (see Ducoux et al., 2020). Complex tectonic structure. |
UNIQUE_ID | 40 |
Minning exploitations within <2km? | Y |
Historical/Active | Historical (not indexed in the Spanish National Minning Cadastre) |
Exploitation name #1 | n.a. |
Exploitation ID (Spanish National Mining Cadastre) #1 | n.a. |
Municipality #1 | n.a. |
Province #1 | n.a. |
Company #1 | n.a. |
Main minning Products #1 | Pb-Zn |
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UNIQUE_ID | 40 |
Outcropping area (km2) | 0.22854 |
Horizontal intersection area (km2) (when buried) | Not buried |
Depth of intersection area (km2) (when buried) | Not buried |
Max. Width (Km) | 0.9 |
Max. Length (Km) | 2.9 |
Max. Evaporites thickness (km) | 1.1 |
Max. Deformation age (Ma) | 150 |
Min. Deformation age (Ma) | 66 |
Deformation stages | 1 |
UNIQUE_ID | 40 |
Section source | Ducoux, M., Jolivet, L., Callot, J. P., Aubourg, C., Masini, E., Lahfid, A., Hommonay, E., Cagnard, F., Gumiaux, C., Baudin, T., 2019. The Nappe des Marbres unit of the Basque‐Cantabrian Basin: the tectono‐thermal evolution of a fossil hyperextended rift basin. Tectonics, 38(11), 3881-3915. [link] |
Well / Borehole availability #1 | n.a. |
Well / Borehole availability #2 | n.a. |
Available data (Stratigraphy) #1 | Bodego, A., Iriarte, E., López-Horgue, M. A., Álvarez, I., 2018. Rift-margin extensional forced folds and salt tectonics in the eastern Basque-Cantabrian rift basin (western Pyrenees). Marine and Petroleum Geology, 91, 667-682. [link] |
Available data (Stratigraphy) #2 | Ducoux, M., Jolivet, L., Callot, J. P., Aubourg, C., Masini, E., Lahfid, A., Hommonay, E., Cagnard, F., Gumiaux, C., Baudin, T., 2019. The Nappe des Marbres unit of the Basque‐Cantabrian Basin: the tectono‐thermal evolution of a fossil hyperextended rift basin. Tectonics, 38(11), 3881-3915. [link] |
Available data (Stratigraphy) #3 | Bodego, A., Iriarte, E., Agirrezabala, L. M., García-Mondéjar, J., López-Horgue, M. A., 2015. Synextensional mid-Cretaceous stratigraphic architecture of the eastern Basque–Cantabrian basin margin (western Pyrenees). Cretaceous Research, 55, 229-261. [link] |
Available data (Stratigraphy) #4 | Bodego, A., Agirrezabala, L. M., 2013. Syn‐depositional thin‐and thick‐skinned extensional tectonics in the mid‐Cretaceous Lasarte sub‐basin, western Pyrenees. Basin Research, 25(5), 594-612. [link] |
Available data (Stratigraphy) #5 | Küchler, T., 1998. Upper Cretaceous of the Barranca (Navarra, northern Spain); integrated itho-, bio- and event stratigraphy. Part I: Cenomanian through Santonian. Acta Geologica Polonica, 48 (2), 157-180. [link] |
Available data (Stratigraphy) #6 | Pedrera, A., García‐Senz, J., Ayala, C., Ruiz‐Constán, A., Rodríguez‐Fernández, L. R., Robador, A., González Menéndez, L., 2017. Reconstruction of the exhumed mantle across the North Iberian Margin by crustal‐scale 3‐D gravity inversion and geological cross section. Tectonics, 36, 3155-3177. [link] |
Regional Stratigraphy | Pedrera, A., García‐Senz, J., Ayala, C., Ruiz‐Constán, A., Rodríguez‐Fernández, L. R., Robador, A., González Menéndez, L., 2017. Reconstruction of the exhumed mantle across the North Iberian Margin by crustal‐scale 3‐D gravity inversion and geological cross section. Tectonics, 36, 3155-3177. [link] |
Seismic data availability #1 | Pedreira, D., Pulgar, J. A., Gallart, J., Díaz, J., 2003. Seismic evidence of Alpine crustal thickening and wedging from the western Pyrenees to the Cantabrian Mountains (north Iberia). Journal of Geophysical Research: Solid Earth, 108(B4), 2204. [link] |
Seismic data availability #2 | Pedreira, D., 2004. Estructura cortical de la zona de transición entre los Pirineos y la Cordillera Cantábrica [Ph.D. thesis]: Universidad de Oviedo, 364p. [link] |
Seismic data availability #3 | DeFelipe, I., Álvarez Pulgar, F. J., Pedreira Rodríguez, D., 2018. Crustal structure of the Eastern Basque-Cantabrian Zone-western Pyrenees: from the Cretaceous hyperextension to the Cenozoic inversion. Revista de la Sociedad Geológica de España, 31(2), 69-82. [link] |
Available data (Structure) #1 | Ducoux, M., Jolivet, L., Callot, J. P., Aubourg, C., Masini, E., Lahfid, A., Hommonay, E., Cagnard, F., Gumiaux, C., Baudin, T., 2019. The Nappe des Marbres unit of the Basque‐Cantabrian Basin: the tectono‐thermal evolution of a fossil hyperextended rift basin. Tectonics, 38(11), 3881-3915. [link] |
Available data (Structure) #2 | Pedrera, A., García‐Senz, J., Ayala, C., Ruiz‐Constán, A., Rodríguez‐Fernández, L. R., Robador, A., González Menéndez, L., 2017. Reconstruction of the exhumed mantle across the North Iberian Margin by crustal‐scale 3‐D gravity inversion and geological cross section. Tectonics, 36, 3155-3177. [link] |
Available data (Structure) #3 | DeFelipe, I., Pedreira, D., Pulgar, J. A., Van der Beek, P. A., Bernet, M., Pik, R., 2019. Unraveling the Mesozoic and Cenozoic tectonothermal evolution of the eastern Basque‐Cantabrian zone–western Pyrenees by low‐temperature thermochronology. Tectonics, 38(9), 3436-3461. [link] |
Available data (Structure) #4 | Bodego, A., Agirrezabala, L. M., 2013. Syn‐depositional thin‐and thick‐skinned extensional tectonics in the mid‐Cretaceous Lasarte sub‐basin, western Pyrenees. Basin Research, 25(5), 594-612. [link] |
Available data (Structure) #5 | Bodego, A., Iriarte, E., Agirrezabala, L. M., García-Mondéjar, J., López-Horgue, M. A., 2015. Synextensional mid-Cretaceous stratigraphic architecture of the eastern Basque–Cantabrian basin margin (western Pyrenees). Cretaceous Research, 55, 229-261. [link] |
Available data (Structure) #6 | Cámara, P., 2017. Salt and Strike-Slip Tectonics as Main Drivers in the Structural Evolution of the Basque-Cantabrian Basin, Spain. In Permo-Triassic Salt Provinces of Europe, North Africa and the Atlantic Margins (pp. 371-393). Elsevier. [link] |
Available data (Analogue modelling) #1 | n.a. |
Available data (Analogue modelling) #2 | n.a. |
Available data (Analogue modelling) #3 | n.a. |
Available data (Gravimetry – Tomography) #1 | Pedrera, A., García‐Senz, J., Ayala, C., Ruiz‐Constán, A., Rodríguez‐Fernández, L. R., Robador, A., González Menéndez, L., 2017. Reconstruction of the exhumed mantle across the North Iberian Margin by crustal‐scale 3‐D gravity inversion and geological cross section. Tectonics, 36, 3155-3177. [link] |
Available data (Gravimetry – Tomography) #2 | Pedreira, D., Pulgar, J. A., Gallart, J., Díaz, J., 2003. Seismic evidence of Alpine crustal thickening and wedging from the western Pyrenees to the Cantabrian Mountains (north Iberia). Journal of Geophysical Research: Solid Earth, 108(B4), 2204. [link] |
Available data (Gravimetry – Tomography) #3 | Pinto, V., Casas, A., Rivero, L., Torne, M., 2005. 3D gravity modeling of the Triassic salt diapirs of the Cubeta Alavesa (northern Spain). Tectonophysics, 405, 65-75. [link] |
Available data (Geochemistry) #1 | DeFelipe, I., Pedreira, D., Pulgar, J. A., Van der Beek, P. A., Bernet, M., Pik, R., 2019. Unraveling the Mesozoic and Cenozoic tectonothermal evolution of the eastern Basque‐Cantabrian zone–western Pyrenees by low‐temperature thermochronology. Tectonics, 38(9), 3436-3461. [link] |
Available data (Geochemistry) #2 | Ortí, F., García-Veigas, J., Rossell, L., Jurado, M. J., Utrilla, R., 1996. Formaciones salinas de las cuencas triásicas en la Península Ibérica: Caracterización Petrológica y Geoquímica. Cuadernos de Geología Ibérica, 20, 13-35. [link] |
Available data (Geochemistry) #3 | Ducoux, M., Jolivet, L., Callot, J. P., Aubourg, C., Masini, E., Lahfid, A., Hommonay, E., Cagnard, F., Gumiaux, C., Baudin, T., 2019. The Nappe des Marbres unit of the Basque‐Cantabrian Basin: the tectono‐thermal evolution of a fossil hyperextended rift basin. Tectonics, 38(11), 3881-3915. [link] |
Available data (Geochemistry) #4 | Iribar, V., Ábalos, B. 2011. The geochemical and isotopic record of evaporite recycling in spas and salterns of the Basque Cantabrian basin, Spain. Applied geochemistry, 26, 1315-1329. [link] |
Available data (Petrophysics) #1 | Llamas, B., Castañeda, M. C., Laín, C., Pous, J., 2017. Study of the Basque–Cantabrian basin as a suitable region for the implementation of an energy storage system based on compressed air energy storage (CAES). Environmental Earth Sciences, 76(5), 204. [link] |
Available data (Petrophysics) #2 | Soto, R., Beamud, E., Roca, E., Carola, E., Almar, Y., 2017. Distinguishing the effect of diapir growth on magnetic fabrics of syn-diapiric overburden rocks: Basque-Cantabrian basin, Northern Spain. Terra Nova 29, 191-201. [link] |
IGME Geological Map (MAGNA50) Sheet number | 89-Tolosa. [link] |
Other Maps #1 (source) | DeFelipe, I., Álvarez Pulgar, F. J., & Pedreira Rodríguez, D., 2018. Crustal structure of the Eastern Basque-Cantabrian Zone-western Pyrenees: from the Cretaceous hyperextension to the Cenozoic inversion. Revista de la Sociedad Geológica de España, 31 (2), 69-82. [link] |
Other Maps #2 (source) | Ducoux, M., Jolivet, L., Callot, J. P., Aubourg, C., Masini, E., Lahfid, A., Hommonay, E., Cagnard, F., Gumiaux, C., Baudin, T., 2019. The Nappe des Marbres unit of the Basque‐Cantabrian Basin: the tectono‐thermal evolution of a fossil hyperextended rift basin. Tectonics, 38(11), 3881-3915. [link] |
Other related references #1 | Turner, J. P., 1996. Switches in subduction direction and the lateral termination of mountain belts: Pyrenees-Cantabrian transition, Spain. Journal of the Geological Society, 153(4), 563-571. [link] |
Other related references #2 | Tugend, J., Manatschal, G., Kusznir, N. J., Masini, E., Mohn, G., Thinon, I., 2014. Formation and deformation of hyperextended rift systems: Insights from rift domain mapping in the Bay of Biscay‐Pyrenees. Tectonics, 33(7), 1239-1276. [link] |
Other related references #3 | DeFelipe, I., Pedreira, D., Pulgar, J. A., Iriarte, E., Mendia, M., 2017. Mantle exhumation and metamorphism in the B asque‐C antabrian B asin (NS pain): Stable and clumped isotope analysis in carbonates and comparison with ophicalcites in the N orth‐P yrenean Z one (U rdach and L herz). Geochemistry, Geophysics, Geosystems, 18(2), 631-652. [link] |
Other related references #4 | Pesquera, A., Velasco, F., 1997. Mineralogy, geochemistry and geological significance of tourmaline-rich rocks from the Paleozoic Cinco Villas massif (western Pyrenees, Spain). Contributions to Mineralogy and Petrology, 129(1), 53-74. [link] |
UNIQUE_ID | 40 |
Seismic survey name #1 | 9C4-21 |
Across structure? #1 | N (within 3km) |
Seismic profile ID (IGME) #1 | 10000 |
Seismic profile code #1 | 14573 |
Seismic profile name #1 | 21 |
Seismic survey year #1 | 1962 |
Data repository #1 | SIGEOF Data Catalogue (Private access section). ©Instituto Geológico y Minero de España (IGME). https://info.igme.es/SIGEOF/ |
Length (km) #1 | 14.70 |
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UNIQUE_ID | 40 |
X Centroid (Structure shape) | -1.912734 |
Y Centroid (Structure shape) | -1.912734 |
Xmin (Structure shape) | -1.925756 |
Xmax (Structure shape) | -1.890415 |
Ymin (Structure shape) | 43.037166 |
Ymax (Structure shape) | 43.043579 |
Xmin seismic line #1 | -1.913290 |
Xmax seismic line #1 | -1.847001 |
Ymin seismic line #1 | 42.921053 |
Ymax seismic line #1 | 43.037181 |
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