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

Lease, Richard O.; Haeussler, Peter J.; O’Sullivan, Paul B.

doi:10.1002/2015tc004067

Cited by 56 publications

(94 citation statements)

References 123 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…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%

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

et al. 2019

View full text Add to dashboard Cite

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.

show abstract

Section: Geologic Settingmentioning

confidence: 97%

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

et al. 2019

View full text Add to dashboard Cite

show abstract

“…FT and (U–Th)/He data can be acquired on crystals previously analyzed for U–Pb geochronology, aided by analytical advances of laser ablation and noble gas mass spectrometry analyses. This approach includes “double” U–Pb and FT or He analysis of apatite or zircon (Campbell et al, ; Carter & Moss, ; Fosdick et al, ; Lease, Haeussler, & O'Sullivan, ; Odlum & Stockli, ; Rahl et al, ; Reiners et al, ; Ternois et al, ; Thomson et al, ) or U–Pb, FT, and (U–Th)/He “triple” dating (e.g., Carrapa et al, ; Danišík, ; Danišík et al, ). Integration of data from two or more thermochronometric systems with different temperature sensitivities in the same mineral permits a more detailed reconstruction of the thermal history in these settings.…”

Section: Advances In Thermochronometry Systematicsmentioning

confidence: 99%

Innovations in (U–Th)/He, Fission Track, and Trapped Charge Thermochronometry with Applications to Earthquakes, Weathering, Surface‐Mantle Connections, and the Growth and Decay of Mountains

2019

View full text Add to dashboard Cite

A transformative advance in Earth science is the development of low‐temperature thermochronometry to date Earth surface processes or quantify the thermal evolution of rocks through time. Grand challenges and new directions in low‐temperature thermochronometry involve pushing the boundaries of these techniques to decipher thermal histories operative over seconds to hundreds of millions of years, in recent or deep geologic time and from the perspective of atoms to mountain belts. Here we highlight innovation in bedrock and detrital fission track, (U–Th)/He, and trapped charge thermochronometry, as well as thermal history modeling that enable fresh perspectives on Earth science problems. These developments connect low‐temperature thermochronometry tools with new users across Earth science disciplines to enable transdisciplinary research. Method advances include radiation damage and crystal chemistry influences on fission track and (U–Th)/He systematics, atomistic calculations of He diffusion, measurement protocols and numerical modeling routines in trapped charge systematics, development of 4He/3He and new (U–Th)/He thermochronometers, and multimethod approaches. New applications leverage method developments and include quantifying landscape evolution at variable temporal scales, changes to Earth's surface in deep geologic time and connections to mantle processes, the spectrum of fault processes from paleoearthquakes to slow slip and fluid flow, and paleoclimate and past critical zone evolution. These research avenues have societal implications for modern climate change, groundwater flow paths, mineral resource and petroleum systems science, and earthquake hazards.

show abstract

“…Although we have only two Susitna river samples from the northern region, they are nearly identical and provide a self‐consistent signature for that region. The similarity of the age signatures implies that erosion in the lower Susitna River catchment is limited and outpaced by the high erosion that occurs in the upper portion of the catchment within the central Alaska Range [ Lease et al ., ]. The five samples from the eastern region display some variability, as expected by the unique geology of each individual watershed.…”

Section: Provenance Analysismentioning

confidence: 99%

“…The age distributions from the northern region match other detrital zircon U‐Pb ages from modern rivers in that region; ages suggest that most of the sediment is derived from plutonic rocks in the headwaters of the watersheds (central Alaska Range), with very little recycled from the Paleozoic and Mesozoic strata [ Finzel et al ., ; Lease et al ., ]. Furthermore, the lack of Jurassic and older grains in our Susitna River samples suggests that there is very little input from the widespread Jurassic igneous rocks composing the northern Talkeetna Mountains (Figure ).…”

Section: Provenance Analysismentioning

confidence: 99%

Miocene‐Recent sediment flux in the south‐central Alaskan fore‐arc basin governed by flat‐slab subduction

Finzel

Enkelmann

2017

Geochem Geophys Geosyst

View full text Add to dashboard Cite

The Cook Inlet in south‐central Alaska contains the early Oligocene to Recent stratigraphic record of a fore‐arc basin adjacent to a shallowly subducting oceanic plateau. Our new measured stratigraphic sections and detrital zircon U‐Pb geochronology and Hf isotopes from Neogene strata and modern rivers illustrate the effects of flat‐slab subduction on the depositional environments, provenance, and subsidence in fore‐arc sedimentary systems. During the middle Miocene, fluvial systems emerged from the eastern, western, and northern margins of the basin. The axis of maximum subsidence was near the center of the basin, suggesting equal contributions from subsidence drivers on both margins. By the late Miocene, the axis of maximum subsidence had shifted westward and fluvial systems originating on the eastern margin of the basin above the flat‐slab traversed the entire width of the basin. These mud‐dominated systems reflect increased sediment flux from recycling of accretionary prism strata. Fluvial systems with headwaters above the flat‐slab region continued to cross the basin during Pliocene time, but a change to sandstone‐dominated strata with abundant volcanogenic grains signals a reactivation of the volcanic arc. The axis of maximum basin subsidence during late Miocene to Pliocene time is parallel to the strike of the subducting slab. Our data suggest that the character and strike‐orientation of the down‐going slab may provide a fundamental control on the nature of depositional systems, location of dominant provenance regions, and areas of maximum subsidence in fore‐arc basins.

show abstract

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

Cited by 56 publications

References 123 publications

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

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

Innovations in (U–Th)/He, Fission Track, and Trapped Charge Thermochronometry with Applications to Earthquakes, Weathering, Surface‐Mantle Connections, and the Growth and Decay of Mountains

Miocene‐Recent sediment flux in the south‐central Alaskan fore‐arc basin governed by flat‐slab subduction

Contact Info

Product

Resources

About