Intense localized rock uplift and erosion in the St Elias orogen of Alaska

Enkelmann, Eva; Zeitler, Peter K.; Pavlis, Terry L.; Garver, John I.; Ridgway, Kenneth D.

doi:10.1038/ngeo502

Cited by 99 publications

(172 citation statements)

References 23 publications

(21 reference statements)

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“…Most studies use thermochronometry on bedrock samples but the use of detrital samples has been shown to be a powerful tool and became increasingly popular (e.g., Enkelmann et al, 2009Enkelmann et al, , 2011Enkelmann et al, , 2015Stock et al, 2006;Rahl et al, 2007;Vermeesch, 2007Vermeesch, , 2013Whipp et al, 2009;Avdeev et al, 2011;Thomson et al, 2013). Although there is a general loss of the spatial information of where the cooling age is sourced within the catchment, there are several advantages that come with dating detrital material: (1) the age distribution of a detrital sample can provide an integrated picture of the cooling age pattern for the entire catchment, (2) using detrital thermochronometry on sedimentary strata of known depositional age allows quantification of changes in either the source rock exhumation rates, or catchment area through time (e.g., Bernet and Garver, 2005;Bernet et al, 2009), and (3) detrital samples can provide age information from regions that may be otherwise inaccessible for bedrock sampling due to thick vegetation cover, lacking infrastructure, political reasons, landscapes that are too steep, or ice coverage.…”

Section: Thermochronologymentioning

confidence: 99%

“…For example, in the St. Elias Mountains in southeast Alaska, massive glaciers and ice fields obstruct the study of rock exhumation by means of bedrock thermochronology. Detrital zircon and apatite FT dating of sediment derived from more than 50 glacial catchments was able to reveal the spatial and temporal pattern of rock exhumation across the entire mountain range (Enkelmann et al, 2008(Enkelmann et al, , 2009Falkowski et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Evaluation of detrital thermochronology for quantification of glacial catchment denudation and sediment mixing

Enkelmann

Ehlers

2015

Chemical Geology

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Section: Thermochronologymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evaluation of detrital thermochronology for quantification of glacial catchment denudation and sediment mixing

Enkelmann

Ehlers

2015

Chemical Geology

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“…These strata are interpreted to have been deposited along the northern margin of flat-slab subduction ( Fig. 16.1 Berger et al, 2008;Enkelmann et al, , 2009Arkle et al, 2009;Sendziak et al, 2009;Benowitz et al, 2011). We interpret exhumation as a product of insertion of buoyant, thick oceanic crust of the Yakutat microplate beneath southern Alaska (Finzel et al, 2011).…”

Section: Basin Inversion Above Flat-slab Regionmentioning

confidence: 99%

Modification of Continental Forearc Basins by Flat‐Slab Subduction Processes: A Case Study from Southern Alaska

Ridgway

Trop

Finzel

2011

Tectonics of Sedimentary Basins

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Forearc basins are large sediment repositories that develop in the upper plate of convergent margins and are a direct response to subduction. These basins are part of the magmatic arc-forearc basin-accretionary prism "trinity" that defines the tectonic configuration of the upper plate along most subduction-related convergent margins. Many previous studies of forearc basins have explored the links between construction of magmatic arcs, exhumation of accretionary prisms, and sediment deposition in adjacent forearc basins. These studies provide an important framework for understanding firstorder tectonic processes recorded in forearc basins that are characterized by long-lived subduction of "normal" oceanic crust. Many convergent margins, however, are complicated by second-order subduction processes, such as flat-slab subduction of buoyant oceanic crust in the form of seamounts, spreading and aseismic ridges, and oceanic plateaus. These second-order processes can substantially modify the tectonic configuration of the upper plate both in time and space, and produce sedimentary basins that do not easily fit into the conventional magmatic arc-forearc basin-accretionary prism trinity.In this chapter, we discuss the modification of the southern Alaska forearc basin by Paleocene-Eocene subduction of a spreading ridge followed by OligoceneHolocene subduction of thick oceanic crust. This thick oceanic crust is currently being subducted beneath south-central Alaska and has an imaged maximum thickness of 30 km at the surface and 22 km at depth. Findings from southern Alaska suggest that forearc basins modified from flat-slab subduction processes may contain a sedimentary and volcanic stratigraphic record that differs substantially from typical forearc basins. Processes and sedimentary features that characterize modified forearc basins include the following: (1) flat-slab subduction of a buoyant, topographically elevated spreading ridge oriented subparallel to the margin prompts diachronous uplift of the forearc basin floor and exhumation of older marine forearc basin strata as the ridge is subducted. Passage of the spreading ridge leads to subsidence and renewed deposition of nonmarine sedimentary and volcanic strata that locally exceeds the thickness of the underlying marine strata. (2) Insertion of a slab window beneath the forearc basin during spreading ridge subduction produces local intrabasinal topographic highs with adjacent depocenters, as well as discrete volcanic centers within and adjacent to the forearc basin. (3) Flat-slab subduction of thick oceanic crust also results in surface uplift and exhumation of forearc basin sedimentary strata. However, the insertion of thick crust throughout the flat-slab region (i.e., lack of a slab window) inhibits subduction-related magmatism adjacent to the forearc basin. In the case of subduction of a >350-km-wide fragment of thick oceanic crust beneath south-central Alaska, exhumation of forearc basin strata located above the region of flat-slab subduction has prompted enhanced T...

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“…The St. Elias Range provides the opportunity for direct field investigations of glacial erosion processes in an active orogen and testing glacial erosion models (e.g. Spotila et al, 2004;Enkelmann et al, 2009Enkelmann et al, , 2010Spotila and Berger, 2010;Headley et al, 2013).…”

Section: Mountain Building and Erosionmentioning

confidence: 99%

“…Headley et al, 2013 Enkelmann et al (2008Enkelmann et al ( , 2009Enkelmann et al ( , 2010. zHe and aHe: zircon and apatite U-Th/He ages of bedrock samples (data from O'Sullivan and Currie, 1996;Enkelmann et al, 2010 Grabowski et al, 2013 Grabowski et al, 2013) Portage lies along the axis of maximum coseismic subsidence in 1964.…”

mentioning

confidence: 99%

Seismic and non-seismic influences on coastal change in Alaska--Fieldtrip guide and conference abstracts, 5th International Conference of IGCP 588

Barlow¹,

Koehler²

2015

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Intense localized rock uplift and erosion in the St Elias orogen of Alaska

Cited by 99 publications

References 23 publications

Evaluation of detrital thermochronology for quantification of glacial catchment denudation and sediment mixing

Evaluation of detrital thermochronology for quantification of glacial catchment denudation and sediment mixing

Modification of Continental Forearc Basins by Flat‐Slab Subduction Processes: A Case Study from Southern Alaska

Seismic and non-seismic influences on coastal change in Alaska--Fieldtrip guide and conference abstracts, 5th International Conference of IGCP 588

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