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Wolff, Reinhard, Hetzel, Ralf, Dunkl, István, Anczkiewicz, Aneta A., Pomella, Hannah (2020) Fast cooling of normal-fault footwalls: Rapid fault slip or thermal relaxation?. Geology, 48 (4) 333-337 doi:10.1130/g46940.1

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Reference TypeJournal (article/letter/editorial)
TitleFast cooling of normal-fault footwalls: Rapid fault slip or thermal relaxation?
JournalGeology
AuthorsWolff, ReinhardAuthor
Hetzel, RalfAuthor
Dunkl, IstvánAuthor
Anczkiewicz, Aneta A.Author
Pomella, HannahAuthor
Year2020 (April 1)Volume48
Issue4
PublisherGeological Society of America
DOIdoi:10.1130/g46940.1Search in ResearchGate
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Mindat Ref. ID144124Long-form Identifiermindat:1:5:144124:0
GUID0
Full ReferenceWolff, Reinhard, Hetzel, Ralf, Dunkl, István, Anczkiewicz, Aneta A., Pomella, Hannah (2020) Fast cooling of normal-fault footwalls: Rapid fault slip or thermal relaxation?. Geology, 48 (4) 333-337 doi:10.1130/g46940.1
Plain TextWolff, Reinhard, Hetzel, Ralf, Dunkl, István, Anczkiewicz, Aneta A., Pomella, Hannah (2020) Fast cooling of normal-fault footwalls: Rapid fault slip or thermal relaxation?. Geology, 48 (4) 333-337 doi:10.1130/g46940.1
In(2020, April) Geology Vol. 48 (4) Geological Society of America
Abstract/NotesAbstract
Rapid rock exhumation in mountain belts is commonly associated with crustal-scale normal faulting during late-orogenic extension. The process of normal faulting advects hot footwall rocks toward Earth’s surface, which shifts isotherms upwards and increases the geothermal gradient. When faulting stops, this process is reversed and isotherms move downwards during thermal relaxation. Owing to these temporal changes of the geothermal gradient, it is not straightforward to derive the history of faulting from mineral cooling ages. Here, we combine thermochronological data with thermokinematic modeling to illustrate the importance of syntectonic heat advection and posttectonic thermal relaxation for a crustal-scale normal fault in the European Alps. The north-south–trending Brenner fault defines the western margin of the Tauern window (Austria) and caused the exhumation of medium-grade metamorphic rocks during Miocene orogen-parallel extension of the Alps. We analyzed samples from a 2-km-thick crustal section, including a 1000-m-long drill core. Zircon and apatite (U-Th)/He ages along this transect increase with elevation from ca. 8 to ca. 10 Ma and from ca. 7 to ca. 9 Ma, respectively, but differ by only ∼1 m.y. in individual samples. Thermokinematic modeling of the ages indicates that the Brenner fault became active at 19 ± 2 Ma and caused 35 ± 10 km of crustal extension, which is consistent with independent geological constraints. The model results further suggest that the fault slipped at a total rate of 4.2 ± 0.9 km/m.y. and became inactive at 8.8 ± 0.4 Ma. Our findings demonstrate that both syntectonic heat advection and posttectonic thermal relaxation are responsible for the cooling pattern observed in the footwall of the Brenner normal fault.

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Wolff, Reinhard, Hölzer, Kyra, Hetzel, Ralf, Dunkl, István, Anczkiewicz, Aneta A. (2024) Late-orogenic extension ceases with waning plate convergence: The case of the Simplon normal fault (Swiss Alps) Journal of Structural Geology, 179. 105049 doi:10.1016/j.jsg.2024.105049
Wolff, Reinhard, Hetzel, Ralf, Dunkl, István, Xu, Qiang, Bröcker, Michael, Anczkiewicz, Aneta A. (2019) High-Angle Normal Faulting at the Tangra Yumco Graben (Southern Tibet) since ∼15 Ma. The Journal of Geology, 127 (1) 15-36 doi:10.1086/700406
Wolff, Reinhard, Hetzel, Ralf, Dunkl, István, Anczkiewicz, Aneta A. (2021) New constraints on the exhumation history of the western Tauern Window (European Alps) from thermochronology, thermokinematic modeling, and topographic analysis. International Journal of Earth Sciences, 110 (8) 2955-2977 doi:10.1007/s00531-021-02094-w
Wolff, Reinhard, Hölzer, Kyra, Hetzel, Ralf, Xu, Qiang, Dunkl, István, Anczkiewicz, Aneta A., Li, Zhenyu (2022) Spatially focused erosion in the High Himalaya and the geometry of the Main Himalayan Thrust in Central Nepal (85°E) from thermo-kinematic modeling of thermochronological data in the Gyirong region (southern China) Tectonophysics, 834. 229378 doi:10.1016/j.tecto.2022.229378
Densmore, A. L., Hetzel, R., Ivy-Ochs, S., Krugh, W. C., Dawers, N., Kubik, P. (2009) Spatial variations in catchment-averaged denudation rates from normal fault footwalls. Geology, 37 (12) 1139-1142 doi:10.1130/g30164a.1
Wolff, Reinhard, Wölfler, Andreas, Hampel, Andrea, Dunkl, István (2024) Constraining the slip history of the Katschberg normal fault (Eastern Tauern Window) by thermo-kinematic modeling: Implications for the tectonic evolution of the Eastern European Alps in the late Cenozoic. Tectonophysics, 890. doi:10.1016/j.tecto.2024.230514
Wölfler, Andreas, Wolff, Reinhard, Hampel, Andrea, Hetzel, Ralf, Dunkl, István (2023) Phases of Enhanced Exhumation During the Cretaceous and Cenozoic Orogenies in the Eastern European Alps: New Insights From Thermochronological Data and Thermokinematic Modeling. Tectonics, 42 (9) doi:10.1029/2022tc007698
Hampel, Andrea, Hetzel, Ralf, Densmore, Alexander L. (2007) Postglacial slip-rate increase on the Teton normal fault, northern Basin and Range Province, caused by melting of the Yellowstone ice cap and deglaciation of the Teton Range?. Geology, 35 (12) 1107 doi:10.1130/g24093a.1
Hölzer, Kyra, Wolff, Reinhard, Hetzel, Ralf, Dunkl, István (2024) The Long-Lasting Exhumation History of the Ötztal-Stubai Complex (Eastern European Alps): New Constraints from Zircon (U–Th)/He Age-Elevation Profiles and Thermokinematic Modeling. Lithosphere, 2024 (1) doi:10.2113/2024/lithosphere_2023_174
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Sanders, Diethard, Ortner, Hugo, Pomella, Hannah (2018) Stratigraphy and deformation of Pleistocene talus in relation to a normal fault zone (central Apennines, Italy) Sedimentary Geology, 373. 77-97 doi:10.1016/j.sedgeo.2018.05.013
 
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