Person:
Muñoz Martín, Alfonso

First Name

Alfonso

Last Name

Muñoz Martín

URI

https://hdl.handle.net/20.500.14352/75220

Affiliation

Universidad Complutense de Madrid

Faculty / Institute

Ciencias Geológicas

Department

Geodinámica, Estratigrafía y Paleontología

Area

Geodinámica Interna

Identifiers

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Now showing 1 - 10 of 36

Análisis integrado de la topografía y anomalías graviméticas en modelación análoga: un modelo de evolución del relieve en la Península Ibérica
(Revista de la Sociedad Geológica de España, 2011) Fernández-Lozano, Javier; Sokoutis, Dimitrios; Willingshofer, Erns; Muñoz Martín, Alfonso; Vicente Muñoz, Gerardo de; Cloetingh1, Sierd
El análisis integrado de la topografía y las anomalías gravimétricas en la Península Ibérica invoca a la presencia de grandes pliegues que afectan a toda la litosfera como precursores de los relieves E-O a NE-SO que se distribuyen por el Macizo Varisco, así como a un mecanismo de engrosamiento cortical nucleado a partir de fallas Tardi-Variscas, como origen del relieve del este peninsular (Cadena Ibérica-Costero Catalana), con patrones dominantes E-O, NE-SO y NO-SE. El modo de deformación, así como el estilo, dependen tanto de las propiedades reológicas iniciales de una litosfera a otra (litosfera resistente Varisca hacia el oeste peninsular/litosfera débil y caliente resultado de la extensión Mesozoica hacia el este) como a los accidentes tectónicos pre-existentes. Presentamos una nueva metodología aplicada a la modelación análoga, basada en el estudio del espectro de las anomalías gravimétricas y la topografía que nos han permitido inferir los procesos responsables de la asimetría en el patrón del relieve intra-placa de la Península Ibérica. A su vez, nuestros resultados arrojan luz sobre los mecanismos generadores del relieve en zonas de intra-placa donde la escasez o falta de resolución de los perfiles sísmicos y geomagnéticos impide la interpretación de la parte más profunda de la litosfera como Asia Central o los Atlas del norte de África.
Estructura alpina del antepaís ibérico
(Geología de España, 2004) Vicente Muñoz, Gerardo de; Muñoz Martín, Alfonso; Guimerà Rosso, Joan; Vegas, Ramón; Cloetingh, Sierd; Vicente Muñoz, Gerardo de
Relación entre la complejidad estructural frágil y la distribución espacial de la sismicidad en tres regímenes tectónicos diferentes (Sur de Centro América)
(Geotemas, 2000) Muñoz Martín, Alfonso; Arcila, M.; Pérez López, Raúl; Rodríguez Pascua, Miguel Angel; Vicente Muñoz, Gerardo de
Fracturation process is the main geological mechanism for earthquakes generation as well as their magnitude and spatial distribution. In this work we analyze the correlation among a geometric, cinematic and dynamic fault-slip analysis with the magnitude frequency distribution (Ms) and the epicentral setting into three different tectonic areas. In order to compare all these parameters these areas have the same surface (2°x2°) and a similar number of epicentres. The brittle structural complexity has been defined by means an index which depends on the number of active structures as well as the different type of active faults under the present-day stress tensor. The obtained results seem indicate that a bigger index of brittle structural complexity has a good relationship with an increasing of the "b" value and with a bigger complexity in the spatial distribution of earthquakes defined by the fractal dimension (capacity dimension, Dcap).
Análisis de la geometría en profundidad de fracturas conductoras en zonas de baja permeabilidad mediante tomografía eléctrica (El Berrocal, Sistema Central Español)
(Geogaceta, 2007) Muñoz Martín, Alfonso; Olaiz Campos, Antonio José; Vicente Muñoz, Gerardo de; Antón López, Loreto; Elorza, Francisco José; Vicente, Raquel de
The groundwater flow in zones of low permeability, as granites, is mainly associated with zones of fracture. For this reason the characterization of the fractures is fundamental, both in surface as in depth, and must integrate geological information (geological mapping, structural analysis), geophysics (mainly electrical and electromagnetic methods) and geochemistry (radon and others gases) with hydrogeology. In this work we analyze the geophysical response of a strike-slip fault zone by means of three 2D resistivity models. The objective is to investigate the presence of several conductive zones and their geometry in depth. The obtained results allow to control the geometry in depth of the fractures, the gaps between the different mapped traces along the fault zone as well as the thickness of landfill. All this information will be useful for the hidromechanical simulation of the massif, and to check the geometry and gas permeability calculated from emanometry.
The Madrid Basin and the Central System: A tectonostratigraphic analysis from 2D seismic lines
(Tectonophysics, 2013) Vicente Muñoz, Gerardo de; Muñoz Martín, Alfonso
Data from deep boreholes, seismic surveys, and surface geology are used to reconstruct the sedimentary infilling of the Cenozoic Madrid Basin. Eight main depositional sequences and seismic units are recognised. From the Paleogene, the latter four of these sedimentary sequences were deposited in a continental environment, under the influence of tectonic activity in the Central System, the Toledo Mountains, the Iberian Chain, and the Sierra de Altomira. The sedimentary infill shows an overall coarsening-upward trend from upper Cretaceous formations to syn-tectonic conglomerate deposits, followed by a fining-upward sequence and moderate reactivation of some faults during the late Miocene–Pliocene. The syn-tectonic sediments are Oligocene–early Miocene in age. The foredeep is oriented northeast–southwest and shows a sediment thickness of up to 3800 m in areas close to the Central System. Several types of tectonic structures are recognised, including imbricate thrust systems, thrust triangle zones, fault-propagation folds, back-thrust systems, and pop-up structures. The frontal thrusts were subjected to significant erosion, and late Miocene sediments onlap the anticlines of the onshore foreland. NW–SE-trending positive flower structures have been recognised in the eastern part of the basin. The total northwest–southeast shortening across the contact between the Madrid Basin and the Central System is approximately 5 km, of which 2–3 km occurred across the Southern Border Thrust. The simultaneous basement uplift of the Central System and the tectonic escape of the Sierra de Altomira have been interpreted as a consequence of constrictive deformation within the “Pyrenean” foreland of the Iberian microplate.
Local stress fields and intraplate deformation of Iberia: variations in spatial and temporal interplay of regional stress sources
(Tectonophysics, 1999) Andeweg, Bernd; Vicente Muñoz, Gerardo de; Cloetingh, Sierd; Giner, Jorge; Muñoz Martín, Alfonso
Tertiary to present deformation in the interior of the Iberian Peninsula reflects spatial and temporal variations of the activity of the plate boundaries. Local deformation patterns observed in many of the numerous intraplate Tertiary basins and their borders, such as the Madrid Basin and the Sierra de Altomira, are at first sight incompatible with the regional stress field under which they were formed. We demonstrate, however, that they can be explained as the effect of several stress fields that acted on the Iberian Peninsula from earliest Tertiary onward. Data on local deformation can constrain both magnitudes and directions of forces acting on the plate boundaries of Iberia, enabling us to estimate the relative importance of the different plate driving and deforming mechanisms providing further constraints on the tectonic evolution of Iberia.
Inversion of moment tensor focal mechanisms for active stresses around the Microcontinent Iberia: Tectonic implications
(Tectonics, 2008) Vicente Muñoz, Gerardo de; Cloetingh, Sierd; Muñoz Martín, Alfonso; Olaiz Campos, Antonio José; Stich, Daniel; Vegas, Ramón; Galindo-Zaldívar, Jesus; Fernández Lozano, Javier
The Iberian microcontinent and its connected oceanic crust are affected by deformations related to the Eurasian-African plate boundary. Active stress inversions from populations of moment tensor focal mechanisms have been performed around and inside the Iberian peninsula, using a total of 213 moment tensor estimates. Main results are: 1) The tensorial solutions show better consistency and lower misfits compared to those obtained previously from first P arrival focal mechanisms. 2) Along the Eurasia- Africa western boundary, the type of active stresses progressively changes easternwards from triaxial extension to uniaxial compression along the Terceira Ridge, the Gloria Fault zone and the Gulf of Cadiz. 3) In the Betics-Alboran-Rif zone, uniaxial extension predominates with Shmax N155ºE trending. 4) In N Algeria, uniaxial compression reappears. 5) The Iberian foreland is currently under strike-slip to uniaxial extension tensorial conditions.
Finite-element modelling of Tertiary paleostress fields in the eastern part of the Tajo Basin (central Spain)
(Tectonophysics, 1998) Muñoz Martín, Alfonso; Cloetingh, Sierd; Vicente Muñoz, Gerardo de; Andeweg, Bernd
Three subsequent Tertiary paleostress fields that are deduced from fault-slip data for the eastern part of the Tajo Basin are analyzed by finite-element studies. The modelling results show that maximum horizontal stresses (SHmax) are mainly controlled by the geometry of the model limits and the boundary conditions applied. The models are used to test two hypotheses on the origin of the Altomira Range. A local stress field responsible for its formation (‘Altomira') can be modelled successfully by superposition in time and place of two major paleostress fields (‘Iberian' and ‘Guadarrama'). Stress trajectories have been modelled with respect to a homogeneous cover and heterogeneous basement to investigate the role of rheological contrasts between different basement blocks on the orientation of the stress field. Results of this kind of modelling suggest a mechanical decoupling between the cover and the basement, especially for the ‘Altomira' paleostress field.
Análisis tensorial de la deformación superpuesta en el límite oriental de la cuenca de Madrid
(Cadernos do Laboratorio Xeolóxico de Laxe, 1994) Muñoz Martín, Alfonso; Vicente Muñoz, Gerardo de; González Casado, José Manuel
An analysis of Neogene brittle deformation using fault population analysis methods has been carried out between the SW border of the Iberian Range and Altomira Range. Two main paleostress fields have been established: 1) N70E - N120E compression (Altomira paleostress field) ofLate Oligocene - Early Miocene age that induced the formation of the SW border of Iberian Range and Altomira - Pareja thrust belts with reverse and strike-slip faults. 2) N140-N160E compression (Guadarrama paleostress field) of Middle Aragonian - early Pleistocene age that reactivated previous faults with strikeslip movement along the Iberian Range. A superposition of two regional stress fields (Iberian and Guadarrama) is proposed to explain E-W compression that formed Altomira Range. Stress tensorial additions have been realized to check this hypothesis.
Origen y relación entre las deformaciones y esfuerzos alpinos en la zona centro-oriental de la Península Ibérica
(Revista de la Sociedad Geológica de España, 1998) Muñoz Martín, Alfonso; Vicente Muñoz, Gerardo de
En este trabajo se realiza una correlación entre los principales datos estructurales, cinemáticos, paleogeográficos, y de resultados de modelos de elementos finitos obtenidos en el borde oriental de la Cuenca del Tajo, con numerosos trabajos previos realizados por otros autores. La integración de estas fuentes de información ha permitido establecer una evolución conjunta para el sector centro-oriental de la placa Ibérica en dos episodios principales: a) El primero está relacionado con una fuerte actividad en el margen N de la placa Ibérica, desde los 5 1 Ma hasta los 38 Ma (Eoceno inferior - Oligoceno inferior), en la que se produciría la estructuración Pirenaica principal. Durante este periodo se desarrollarían, relacionados con el antepaís pirenaico, los siguientes cinturones de deformación bajo un campo de esfuerzos general NNE-SSO a NE-SO: la Rama Aragonesa de la Cordillera Ibérica y el sector meridional de la Sierra de Altomira y, en menor medida, la Rama Castellana de la Cordillera Ibérica y el Sistema Central. Durante el Oligoceno superior- Mioceno inferior (entre los 38 Ma y los 24 Ma) se desarrolló una etapa intermedia con actividad tectónica simultánea en los márgenes N y S de la placa Ibérica. Asociada a esta etapa se desarrolló un campo de paleoesfuerzos local compresivo E-O en la zona de antepaís común de los Pirineos y las Béticas, responsable de la estructuración principal de los sectores central y septentrional de la Sierra de Altomira. La Sierra de Altomira se interpreta como un escape o extrusión de la cobertera hacia el O, favorecido por la presencia de niveles incompetentes del Triásico superior. En este periodo comienzó también el desarrollo de la actividad extensiva en el borde oriental de la península en relación a la apertura del Golfo de Valencia. b) Finalmente, durante el Mioceno medio - actualidad, se desarrolla una mayor actividad en el margen S de la placa Ibérica (estructuración de las Cordilleras Béticas), si bien permanece una cierta actividad en el margen N, como lo demuestra la presencia de sismicidad moderada a lo largo del margen Cantábrico-Pirenaico. Durante este periodo se desarrollaron una serie de deformaciones intraplaca en el antepaís Bético bajo un campo de esfuerzos regional NO-SE: El Sistema Central y la Rama Castellana de la Cordillera Ibérica. Este proceso aparece complicado por dos procesos tectónicos que generaron extensión: 1) Al este en relación a los procesos de rifting del Golfo de Valencia, y al oeste de la Cordillera Ibérica, y a partir del Mioceno superior, en relación a flexiones corticales NE-SO transversales a la dirección regional de σ HMAX. [ABSTRACT] A correlation amongst macro and mesostructural analysis results, kinematic and paleogeographic data, paleostresses and finite element models results has been established in the eastern border of the Tajo Basin. This comparison allows us to establish an evolutionary pattern for the central part of the Iberian plate in two main episodes: a) The first one was related to a strong tectonic activity in the northern border of the Iberian plate during the Lower Eocene to the Upper Oligocene (Pirenees uplift). In this period, the following intraplate chains were formed in the Pyrenees foreland under a regional NNE-SSO compressive stress field: the Aragonian Branch of the Iberian Range and the southern part of the Altomira Range, and to a lesser extent, the Castillian Branch of the Iberian Range and the Spanish Central System. During the Upper Oligocene and Lower Miocene a transition between the two main episodes, with tectonic activity in both borders of the Iberian plate (Pyrenees and Betics), took place. Related to this episode a E-O local compressive stress field is developed in the eastern border of the Tajo Basin (Altomira Stress field). This stress field generated a N-S fold and thrust belt west verging that affected the Mesozoic cover. Thus, the Altomira Range is interpreted as a cover extrusion westwards in a regional N-S compression supported by the presence of evaporitic Upper Triassic rocks and the presence of normal basement faults. During this period extension processes in the eastern border of the Iberian plate began associated with the opening of the Valencia Through. b) Finally, from Middle Miocene to Present the main tectonic activity has been developed in the southern border of the Iberian Plate (Betics). However, sorne tectonic activity remained in the northern border of the Iberian plate as it is shown by sorne moderate seismic activity along the Pyrenees and the Cantabrian margino In this period sorne intraplate deformations were developed in the Betic foreland under a NW-SE regional stress field: Spanish Central System and the Castillian Branch of the Iberian Range. This main sketch is complicated by two different extensional processes: 1) doming related to opening of the Valencia Trough, and 2) superficial extension along NE-SO litospheric folding formed perpendicular to the regional Valencia Through. b) Finally, from Middle Miocene to Present the main tectonic activity has been developed in the southern border of the Iberian Plate (Betics). However, sorne tectonic activity remained in the northern border of the Iberian plate as it is shown by sorne moderate seismic activity along the Pyrenees and the Cantabrian margino In this period sorne intraplate deformations were developed in the Betic foreland under a NW-SE regional stress field: Spanish Central System and the Castillian Branch of the Iberian Range. This main sketch is complicated by two different extensional processes: 1) doming related to opening of the Valencia Trough, and 2) superficial extension along NE-SO litospheric folding formed perpendicular to the regional σHMAX.