The role of thrust faulting in the formation of the eastern Alaska Range: Thermochronological constraints from the Susitna Glacier Thrust Fault region of the intracontinental strike-slip Denali Fault system

Riccio, Steven J.; Fitzgerald, Paul G.; Benowitz, Jeff; Roeske, Sarah M.

doi:10.1002/2014tc003646

Cited by 40 publications

(76 citation statements)

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“…ZUPb ages of 90–110 Ma are minor (<8%) or absent in most samples with three exceptions (Figure ). Significant 100 Ma and 93 Ma ZUPb age peaks in the Beluga (#5) and Susitna (#12) catchments, respectively, are likely derived from Late Cretaceous plutons dated within these catchments [ Riccio et al , ; Jones et al , ]. The large component of 90–110 Ma ZUPb ages in the Chulitna catchment (#11) and the minor component in other catchments may be derived from second‐cycle zircons of the Mesozoic Kahiltna flysch [ Hults et al , ] or first‐cycle zircons from unmapped Late Cretaceous plutons.…”

Section: Resultsmentioning

confidence: 99%

“…There is a reasonable match between detrital river and bedrock cooling ages within the same catchments; catchments #4 and #5: 45–49 Ma detrital AFT, 40–55 Ma bedrock feldspar 40 Ar/ 39 Ar minimum ages and AHe [ Benowitz et al , ; R. O. Lease, unpublished bedrock thermochronology data, 2016]; catchment #6: 46 Ma detrital AFT, 35–50 Ma bedrock AFT [ Ward et al , ]; catchments #8 and #9: 51–53 Ma detrital ZFT; 39–52 Ma bedrock ZFT [ Plafker et al , ]; and catchment #12: 37–45 Ma detrital ZFT and AFT, 30–50 Ma bedrock feldspar 40 Ar/ 39 Ar and AFT [ Riccio et al , ]. Detrital cooling age peaks that are coeval with 50–70 or 25–40 Ma magmatism have an uncertain origin, because it is unclear whether these cooling ages reflect postemplacement pluton cooling or erosional exhumation.…”

Section: Discussionmentioning

confidence: 99%

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Changing exhumation patterns during Cenozoic growth and glaciation of the Alaska Range: Insights from detrital thermochronology and geochronology

2016

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Cenozoic growth of the Alaska Range created the highest topography in North America, but the space‐time pattern and drivers of exhumation are poorly constrained. We analyzed U/Pb and fission‐track double dates of detrital zircon and apatite grains from 12 catchments that span a 450 km length of the Alaska Range to illuminate the timing and extent of exhumation during different periods. U/Pb ages indicate a dominant Late Cretaceous to Oligocene plutonic provenance for the detrital grains, with only a small percentage of grains recycled from the Mesozoic and Paleozoic sedimentary cover. Fission‐track ages record exhumation during Alaska Range growth and incision and reveal three distinctive patterns. First, initial Oligocene exhumation was focused in the central Alaska Range at ~30 Ma and expanded outward along the entire length of the range until 18 Ma. Oligocene exhumation, coeval with initial Yakutat microplate collision >600 km to the southeast, suggests a far‐field response to collision that was localized by the Denali Fault within a weak Mesozoic suture zone. Second, the variable timing of middle to late Miocene exhumation suggests independently evolving histories influenced by local structures. Time‐transgressive cooling ages suggest successive rock uplift and erosion of Mounts Foraker (12 Ma) through Denali (6 Ma) as crust was advected through a restraining bend in the Denali Fault and indicate a long‐term slip rate ~4 mm/yr. Third, Pliocene exhumation is synchronous (3.7–2.7 Ma) along the length of the Alaska Range but only occurs in high‐relief, glacier‐covered catchments. Pliocene exhumation may record an acceleration in glacial incision that was coincident with the onset of Northern Hemisphere glaciation.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Changing exhumation patterns during Cenozoic growth and glaciation of the Alaska Range: Insights from detrital thermochronology and geochronology

2016

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“…In the central Alaska Range, rapid cooling at ~6 Ma is documented by apatite FT data from the Denali massif and potentially indicates a change in Pacific Plate convergence direction (Fitzgerald et al, ). Other workers suggest that rapid Neogene cooling of rocks along the CDFZ and other structures is the result of advection of crust through the large restraining bend that characterizes the CDFZ and attendant large‐scale contractional deformation and vertical rock uplift (Figure , inset; Fitzgerald et al, ; Riccio et al, ; Lease et al, ). Bedrock apatite He and detrital apatite FT dates from high‐relief, glaciated catchments adjacent to the CDFZ record accelerated Pleistocene cooling and exhumation as the result of glacial erosion (Benowitz et al, ; Lease, ; Lease et al, ).…”

Section: Geologic Settingmentioning

confidence: 97%

“…Phase II kinematics of the EDFZ may have been dominantly strike‐slip relative to Phase I contraction‐dominated deformation, as has been suggested for the CDFZ (Cole et al, ). The bulk of separation measured along the EDFZ is inferred to have occurred ~post‐55 Ma, further suggesting continuing dextral slip along the EDFZ over Phase II (Eisbacher, ; Lanphere, ; Riccio et al, ). Second, the locus of contractional strain and attendant exhumation may have been concentrated elsewhere during Phase II slow cooling in the Kluane Ranges.…”

Section: Geological Interpretations Of Thermal History Exhumation Amentioning

confidence: 99%

Thermotectonic History of the Kluane Ranges and Evolution of the Eastern Denali Fault Zone in Southwestern Yukon, Canada

et al. 2019

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Exhumation and landscape evolution along strike‐slip fault systems reflect tectonic processes that accommodate and partition deformation in orogenic settings. We present 17 new apatite (U‐Th)/He (He), zircon He, apatite fission‐track (FT), and zircon FT dates from the eastern Denali fault zone (EDFZ) that bounds the Kluane Ranges in Yukon, Canada. The dates elucidate patterns of deformation along the EDFZ. Mean apatite He, apatite FT, zircon He, and zircon FT sample dates range within ~26–4, ~110–12, ~94–28, and ~137–83 Ma, respectively. A new zircon U‐Pb date of 113.9 ± 1.7 Ma (2σ) complements existing geochronology and aids in interpretation of low‐temperature thermochronometry data patterns. Samples ≤2 km southwest of the EDFZ trace yield the youngest thermochronometry dates. Multimethod thermochronometry, zircon He date‐effective U patterns, and thermal history modeling reveal rapid cooling ~95–75 Ma, slow cooling ~75–30 Ma, and renewed rapid cooling ~30 Ma to present. The magnitude of net surface uplift constrained by published paleobotanical data, exhumation, and total surface uplift from ~30 Ma to present are ~1, ~2–6, and ~1–7 km, respectively. Exhumation is highest closest to the EDFZ trace but substantially lower than reported for the central Denali fault zone. We infer exhumation and elevation changes associated with ~95–75 Ma terrane accretion and EDFZ activity, relief degradation from ~75–30 Ma, and ~30 Ma to present exhumation and surface uplift as a response to flat‐slab subduction and transpressional deformation. Integrated results reveal new constraints on landscape evolution within the Kluane Ranges directly tied to the EDFZ during the last ~100 Myr.

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“…Riccio et al, 2014).3 Wittmann et al, 2011).4 Puchol et al, 2016).5 Molliex et al, 2016). 6(Hippe et al, 2012).7 Carretier et al, 2015).8 Lupker et al, 2012).…”

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Basinga: A cell‐by‐cell GIS toolbox for computing basin average scaling factors, cosmogenic production rates and denudation rates

Charreau

Blard

Zumaque

et al. 2019

Earth Surf Processes Landf

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The calculation of denudation rates from the measured cosmogenic nuclide concentrations in river sediments requires assumptions and approximations. Several different approaches and numerical tools are available in the literature. A widely used analytical approach represents the muogenic production with one or two exponentials, assumes the attenuation length of muons to be constant and also neglects temporal variations in the Earth's magnetic field. The denudation rates are then calculated directly and analytically from the measured concentrations. A second numerical and iterative approach was more recently proposed and considers a more rigorous muogenic production law based on pre‐calculated variable attenuation length of muons and accounts for temporal changes of the magnetic field. It also assumes a specific distribution of denudation rates throughout the basin and uses an iterative approach to calculate the basin average denudation rates. We tested the two approaches across several natural basins and found that both approaches provide similar denudation results. Hence, assuming exponential muogenic production and constant attenuation length of muons in the rock has little impact on the derived denudation rates. Therefore, unless a priori known distributions of denudation rates are to be tested, there does not appear to be any particular gain from using the second iterative method which is computationally less effective. Based on these findings, we developed and describe here Basinga, a new ArcGIS® and QGIS toolbox which computes the basin average scaling factors, cosmogenic production rates and denudation rates for several tens of drainage basins together. Basinga follows either the Lal/Stone or the Lifton/Sato/Dunai scaling schemes and includes several optional tools for correcting for topographic shielding, ice cover and lithology. We have also developed an original method for correcting the cosmogenic production rates for past variations in the Earth's magnetic field. © 2019 John Wiley & Sons, Ltd.

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The role of thrust faulting in the formation of the eastern Alaska Range: Thermochronological constraints from the Susitna Glacier Thrust Fault region of the intracontinental strike-slip Denali Fault system

Cited by 40 publications

References 105 publications

Changing exhumation patterns during Cenozoic growth and glaciation of the Alaska Range: Insights from detrital thermochronology and geochronology

Changing exhumation patterns during Cenozoic growth and glaciation of the Alaska Range: Insights from detrital thermochronology and geochronology

Thermotectonic History of the Kluane Ranges and Evolution of the Eastern Denali Fault Zone in Southwestern Yukon, Canada

Basinga: A cell‐by‐cell GIS toolbox for computing basin average scaling factors, cosmogenic production rates and denudation rates

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