The Role of Surface Processes in Partitioning of Strain and Uplift, St. Elias Orogen, Southern Alaska

Hooks, Benjamin P.

doi:10.5539/esr.v5n1p76

Cited by 1 publication

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“…Field observations and geomorphology data suggest a very complex set of structures, including reverse, strike‐slip, and normal faults that developed where the northern end of the Fairweather Fault splays off into the Connector Fault and bends to the northwest into the Bagley Fault system (Figure ) [ Bruhn et al ., ]. Numerical models of the indenting plate corner show a strain concentration with significant vertical motion localized at the syntaxis [ Koons et al ., , ; Hooks , ]. Coupled with efficient glacial erosion, this colocation resulted in exhumation of rocks from 8 to 10 km depths in 3–2 Myr.…”

Section: Discussionmentioning

confidence: 99%

Source to sink evaluation of sediment routing in the Gulf of Alaska and Southeast Alaska: A thermochronometric perspective

et al. 2017

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In this study, we present a source to sink evaluation of sediment routing at the glaciated convergent margin in Southeast Alaska. We investigate the efficacy of thermochronology to record spatial and temporal exhumation patterns in synorogenic sediment using Neogene strata drilled by Integrated Ocean Drilling Program Expedition 341 in the Gulf of Alaska. We present 1641 and 529 new detrital zircon and apatite fission track ages, respectively, from strata deposited on the continental shelf, slope, and deep‐sea fans. These data are compared to results from the proposed source terrains, including the St. Elias Mountains and new data from the Alsek River. We find that the offshore Bagley‐Bering sediment contains grains recording cooling ages much older (80–35 Ma) than those reported from the St. Elias syntaxis (3–2 Ma), indicating that extreme rapid exhumation does not extend west of the Seward‐Bagley divide. Data from the sediment on the continental shelf, slope, and proximal deep sea all yield similar results, suggesting the same general source region since 1.2 Ma and limited sediment mixing along this glaciated margin. Data from sediment in the distal deep sea show that extreme, rapid, and deep‐seated exhumation was ongoing at ~11–8 Ma. Overall, this study demonstrates the strengths and limitations of using detrital fission track thermochronology to understand sediment routing on a glaciated convergent margin and to record changes in exhumation rates over geologic time scales.

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Section: Discussionmentioning

confidence: 99%