Difference between revisions of "Tectonic Aneurysms"

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[[File:Science-2015-Zeitler-799-1.png|732px|left]][[File:Science-2015-Zeitler-799-2.png|732px]]
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<h2 id="mp-itn-h2" style="margin:0.5em; width:80em; background:#cedff2; font-family:inherit; font-size:110%; font-weight:normal; border:1px solid #a3b0bf; color:#000; padding:0.2em 0.4em;">
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==Tectonic Aneurysm and Mountain Building==
  
'''See Also''':  
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'''Abstract:''' Some of the most spectacular topography on the planet arises from the product of localized interactions
[[file:Tectonic_Aneurysms_Poster.pdf| Tectonic Aneurysms and Mountain Building]]
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between climate, erosion and tectonics. A notable example emerges when climate and tectonic systems
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mutually influence their thermal structures. In the atmosphere this influence can lead to orographic effects that
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focus precipitation, which is funneled by rivers and glaciers into spatially restricted zones with a high potential
 +
for erosion. Focusing of this erosional power onto the solid Earth at deforming convergent margins then
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perturbs stress fields and the material properties of the lithosphere, diverting the three
 +
-
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dimensional tectonic
 +
velocity field. The resulting rapid ascent of crustal material produces a hot and correspondingly weak domain
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in the upper crust. This weak domain further concentrates strain, generating the zone of stable, rapid uplift and
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exhumation that we refer to as a tectonic aneurysm. The tectonic aneurysm is characterized by extreme relief
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where rapid exhumation has been sustained (for 3 Myr or more) and very young metamorphic assemblages
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are exposed adjacent to exceptionally powerful fluvial (~200 kW/m or more) or glacial (~40 kW/m ) erosional
 +
agents. This characteristic ensemble of metamorphic, surface, and tectonic features, that together constitutes
 +
the tectonic aneurysm, are present to varying degrees in the three examples that we review: Nanga Parbat,
 +
northwest Pakistan; Namche Barwa, southeast Tibet; and St Elias, southeast Alaska. Petrologic, geomorphic,
 +
and geodynamic investigations of these three extreme regions, summarized here, illuminate the non-linear
 +
interaction and cooperative behavior of tectonics and surface processes, which are likely universal, but are
 +
most clearly manifested in these regions where the high process rates produce a high signal to noise ratio.
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</h2>
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<pdf>File:Tectonic_Aneurysms_Poster.pdf</pdf>

Latest revision as of 14:05, 20 April 2018

Tectonic Aneurysm and Mountain Building

Abstract: Some of the most spectacular topography on the planet arises from the product of localized interactions between climate, erosion and tectonics. A notable example emerges when climate and tectonic systems mutually influence their thermal structures. In the atmosphere this influence can lead to orographic effects that focus precipitation, which is funneled by rivers and glaciers into spatially restricted zones with a high potential for erosion. Focusing of this erosional power onto the solid Earth at deforming convergent margins then perturbs stress fields and the material properties of the lithosphere, diverting the three - dimensional tectonic velocity field. The resulting rapid ascent of crustal material produces a hot and correspondingly weak domain in the upper crust. This weak domain further concentrates strain, generating the zone of stable, rapid uplift and exhumation that we refer to as a tectonic aneurysm. The tectonic aneurysm is characterized by extreme relief where rapid exhumation has been sustained (for 3 Myr or more) and very young metamorphic assemblages are exposed adjacent to exceptionally powerful fluvial (~200 kW/m or more) or glacial (~40 kW/m ) erosional agents. This characteristic ensemble of metamorphic, surface, and tectonic features, that together constitutes the tectonic aneurysm, are present to varying degrees in the three examples that we review: Nanga Parbat, northwest Pakistan; Namche Barwa, southeast Tibet; and St Elias, southeast Alaska. Petrologic, geomorphic, and geodynamic investigations of these three extreme regions, summarized here, illuminate the non-linear interaction and cooperative behavior of tectonics and surface processes, which are likely universal, but are most clearly manifested in these regions where the high process rates produce a high signal to noise ratio.