Autor: |
García Morabito, Ezequiel, Beltrán‐Triviño, Alejandro, Terrizzano, Carla M., Bechis, Florencia, Likerman, Jeremías, Von Quadt, Albrecht, Ramos, Víctor A. |
Zdroj: |
Tectonics; Feb2021, Vol. 40 Issue 2, p1-28, 28p |
Abstrakt: |
Theoretical studies support the idea that the internal dynamics of actively deforming mountain ranges are influenced by spatial and temporal variations in climate. The identification of plausible correlations between orogen behavior and external climatic processes requires, among other factors, that the initiation and duration of any deformation event be precisely constrained. Here, we add new detrital zircon U‐Pb ages and 10Be surface exposure dating to the already extensive data set for the low‐temperature cooling history, to analyze the spatial patterns of deformation, and their temporal variations across the foreland of North Patagonia, with the aim of evaluating potential feedbacks between climate and deformation. Stratal relationships, together with geomorphic evidences of deformation document the precise timing of individual structures within the fold‐thrust belt and the broken foreland. Our data record a progressive decrease of upper‐plate shortening rates and subsidence after a first period of widespread deformation and uplift (ca. 13–7 Ma). This "transitional" foreland phase coeval to the onset of glacial conditions at 7.4–5 Ma is followed by a structural reorganization after ca. 3 Ma, marked by the abandonment of the foreland and enhanced slip on interior faults, with the intensification of glacial erosion at this time. We propose that acceleration in erosion rates during the past 7 Ma may have influenced the regional geometry and kinematic history of the orogenic belt. Our empirical results match theoretical predictions and provide compelling evidence at the scale of individual thrust faults for the significant impact of climate change on orogenic behavior. Key Points: U‐Pb and 10Be SED from N Patagonia constrain patterns of deformation, and their temporal variations during a major climatic transitionData record a progressive decrease of upper‐plate shortening after a first period of widespread deformation and uplift (13–7 Ma)Acceleration in erosion rates during the past 7 Ma may have influenced the regional geometry and kinematic history of the orogenic belt [ABSTRACT FROM AUTHOR] |
Databáze: |
Complementary Index |
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