Normal faulting and mass movement during ridge subduction inferred from porosity transition and zeolitization in the Costa Rica subduction zone

Estudiamos la distribución frecuencia-magnitud a lo largo de la trinchera mesoamericana (MAT), usando 2345 eventos del periodo 1964-1994. Utilizamos el catalogo regional MIDAS con magnitud de completitud de 4.2. Para mapear el valor b como función de la profundidad (enfoque unidimensional), aplicamos el procedimiento de ventanas deslizantes en la vertical. Cada ventana contiene un número constante de eventos. Para obtener más detalles en la distribución del valor b, proyectamos los hipocentros del catálogo en tres regiones (aproximadamente Guatemala-El Salvador, Nicaragua, Costa Rica), hacia planos perpendiculares a la trinchera. Luego, calculamos el valor b en volúmenes cilíndricos deslizantes (enfoque bidimensional) que contienen un número constante de eventos y con centros en los nodos de un enrejillado de 5 km x 5 km. El valor b varía significativamente a lo largo de la MAT. Identificamos valores altos de b en la parte superior de la litosfera subducida, a profundidades de 80-110 km por debajo de Guatemala y El Salvador, y a profundidades de 130-170 km por debajo de Nicaragua. Localizamos valores anómalos (altos) de b en la parte inferior de la litosfera, a profundidades de 50-90 km y 50-160 km por debajo de Guatemala-El Salvador y Nicaragua, respectivamente. Las anomalías observadas en la parte superior de la litosfera pueden estar relacionadas con deshidratación e incremento sucesivo de la presión de poro en la litosfera descendiente. Estos, a su vez, producirían el volcanismo que ocurre sobre las anomalías en la parte superior de la litosfera. Las anomalías en la parte inferior de la zona de Wadati-Benioff podrían estar asociadas con el alto gradiente térmico entre la litosfera y el manto.

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Rock and age relationships within the Talkeetna forearc accretionary complex in the Nelchina area, southern Alaska

Canadian Journal of Earth Sciences ◽

10.1139/cjes-2018-0268 ◽

2020 ◽

Vol 57 (6) ◽

pp. 709-724

Author(s):

John Barefoot ◽

Elisabeth S. Nadin ◽

Rainer J. Newberry ◽

Alfredo Camacho

Keyword(s):

Subduction Zone ◽

Elevated Temperatures ◽

Accretionary Prism ◽

Fault System ◽

Petrographic Analysis ◽

Spreading Ridge ◽

Current Configuration ◽

Ridge Subduction ◽

South Central ◽

Subduction Zone Processes

Subduction zone processes are challenging to study because of the rarity of good exposures and the complexity of rock relationships within accretionary prisms. We report the results of field mapping and petrographic, geochemical, and geochronological analyses of the McHugh Complex accretionary prism mélange in south-central Alaska that was recently exposed due to retreat of the Nelchina Glacier. Our new mapping and analyses of the mélange, as well as adjacent Talkeetna arc intrusives, suggests that the previously mapped trace of the Border Ranges fault should shift northward in this location. Detailed petrographic analysis places this mélange exposure with the Potter Creek assemblage of the McHugh Complex. Blocks of pillow lavas within the mélange have both mid-ocean ridge basalt and intra-plate geochemical affinities, attesting to the complex relations of subduction-zone inputs in an alternating erosive–accretionary margin. A new zircon U–Pb age and geochemical analyses of a set of felsic dikes that cross-cut the accretionary sequence provide constraints on the regional tectonic evolution, including near-trench plutonism associated with the migration of a subducting spreading ridge along the southern Alaska margin during the Paleocene–Eocene. The McHugh section and cross-cutting dikes in this location are pervasively hydrothermally altered, which we attribute to elevated temperatures related to ridge subduction. Late-stage motion along the Border Ranges fault system, which is also recorded in the area, may also have contributed to the widespread alteration. Our data indicate that the Talkeetna volcanic arc and associated accretionary prism sediments were in their current configuration by 55 Ma.

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