Aspen anomaly

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Aspen anomaly is a geological structure in Colorado, United States. It consists of a low-seismic velocity anomaly in the mantle which underpins the highest sector of the Rocky Mountains.

Contents

Characteristics

The Aspen anomaly is a seismic velocity anomaly in the mantle beneath central Colorado (in the region of Aspen, Colorado [1] ), [2] which appears to reach down into the upper mantle. [3] Helium with isotope ratios indicative of mantle origin emanates from the terrain above the anomaly. [4] [5]

The Aspen anomaly coincides with the highest region of the Rocky Mountains (such as the San Juan Mountains and the Sawatch Range [6] ) and divergent drainages (Arkansas River, Colorado River and Gunnison River) which have cut deep gorges. This region underwent significant uplift during the Cenozoic [3] starting from 10-5 million years ago and was subsequently eroded by the Colorado River. [7] Ongoing present-day uplift of the San Juan Mountains may be linked to the Aspen anomaly. [5]

River knickpoints in Gore Canyon and Black Canyon may mark the point at which the rivers pass through the edge of the region above the anomaly. [8] The Colorado River may be influenced by the anomaly all the way to Lees Ferry, Arizona. [9]

Hot springs and geysers above the anomaly are a major source of carbon dioxide and other gases, some linked to chemolithotrophic bacterial communities. [4] Cenozoic volcanism is also associated with the anomaly, [10] such as potentially the Twin Lakes pluton close to Leadville, Colorado. [11]

Context

In seismic tomography images, the Aspen anomaly is characterized by a northwards tilted low seismic velocity anomaly. [12] The anomaly is one among several low velocity anomalies beneath the western United States, although unlike the others known as the Jemez, Yellowstone and St. George it does not have a northeastward throw. [2] Other structures that may be related to the Aspen anomaly are the Lester Mountain zone, the Colorado mineral belt and the Rio Grande Rift. [13] The Aspen anomaly has been compared with the Yellowstone hotspot, [3] but it lacks a volcanic caldera that Yellowstone has. [5]

Origin

The Aspen anomaly has been interpreted in several ways.

Related Research Articles

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Subduction A geological process at convergent tectonic plate boundaries where one plate moves under the other

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Mantle plume An upwelling of abnormally hot rock within the Earths mantle

A mantle plume is a proposed mechanism of convection of abnormally hot rock within the Earth's mantle. Because the plume head partly melts on reaching shallow depths, a plume is often invoked as the cause of volcanic hotspots, such as Hawaii or Iceland, and large igneous provinces such as the Deccan and Siberian traps. Some such volcanic regions lie far from tectonic plate boundaries, while others represent unusually large-volume volcanism near plate boundaries.

Seismic tomography is a technique for imaging the subsurface of the Earth with seismic waves produced by earthquakes or explosions. P-, S-, and surface waves can be used for tomographic models of different resolutions based on seismic wavelength, wave source distance, and the seismograph array coverage. The data received at seismometers are used to solve an inverse problem, wherein the locations of reflection and refraction of the wave paths are determined. This solution can be used to create 3D images of velocity anomalies which may be interpreted as structural, thermal, or compositional variations. Geoscientists use these images to better understand core, mantle, and plate tectonic processes.

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Cobb hotspot

The Cobb hotspot is a marine volcanic hotspot at, which is 460 km (290 mi) west of Oregon and Washington, North America, in the Pacific Ocean. Over geologic time, the Earth's surface has migrated with respect to the hotspot through plate tectonics, creating the Cobb-Eicklberg seamount chain. The hotspot is currently collocated with the Juan de Fuca Ridge.

The Jemez Lineament is a chain of late Cenozoic volcanic fields, 600 km long, reaching from the Springerville and White Mountains volcanic fields in East-Central Arizona to the Raton-Clayton volcanic field in Northeastern New Mexico. It was long interpreted as a hot spot trace due to its resemblance in length and azimuth to the Yellowstone hot spot trace, but there is no systematic progression in age along the trace and it is now interpreted as a hydrous subduction zone scar, separating basement rock of the Yavapai-Mazazatl transition zone from the Mazaztl Province proper.

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Low-velocity zone

The low-velocity zone (LVZ) occurs close to the boundary between the lithosphere and the asthenosphere in the upper mantle. It is characterized by unusually low seismic shear wave velocity compared to the surrounding depth intervals. This range of depths also corresponds to anomalously high electrical conductivity. It is present between about 80 and 300 km depth. This appears to be universally present for S waves, but may be absent in certain regions for P waves. A second low-velocity zone has been detected in a thin ≈50 km layer at the core-mantle boundary. These LVZs may have important implications for plate tectonics and the origin of the Earth's crust.

Large low-shear-velocity provinces

Large low-shear-velocity provinces, LLSVPs, also called LLVPs or superplumes, are characteristic structures of parts of the lowermost mantle of the Earth. These provinces are characterized by slow shear wave velocities and were discovered by seismic tomography of the deep Earth. There are two main provinces: the African LLSVP and the Pacific LLSVP. Both extend laterally for thousands of kilometers and possibly up to 1000 km vertically from the core-mantle boundary. The Pacific LLSVP has specific dimensions of 3000 km across and 300 m higher than the surrounding ocean-floor, and is situated over four hotspots that suggest multiple mantle plumes underneath. These zones represent around 8% of the volume of the mantle. Other names for LLSVPs include superwells, thermo-chemical piles, or hidden reservoirs. Some of these names, however, are more interpretive of their geodynamical or geochemical effects, while many questions remain about their nature.

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References

  1. Morgan, Lisa A.; Quane, Steven L. (2010-01-01). Through the Generations: Geologic and Anthropogenic Field Excursions in the Rocky Mountains from Modern to Ancient. Geological Society of America. p. 24. ISBN   9780813700182.
  2. 1 2 Dueker, Yuan & Zurek 2001, p. 6.
  3. 1 2 3 Coblentz, D.D.; van Wijk, J. (December 2007). "Mechanisms of Topographic Uplift for the Southern Rocky Mountains". AGU Fall Meeting Abstracts. 2007: T11C–0723. Bibcode:2007AGUFM.T11C0723C.
  4. 1 2 "CO2-RICH SPRINGS AND TRAVERTINES OF THE ROCKY MOUNTAIN REGION: MANTLE HELIUM ASSOCIATED WITH THE ASPEN ANOMALY AND GEOMICROBIOLOGY OF "CONTINENTAL SMOKERS"". gsa.confex.com. Retrieved 2018-04-08.
  5. 1 2 3 Blair, Rob; Bracksieck, George (2011-09-01). The Eastern San Juan Mountains: Their Ecology, Geology, and Human History. University Press of Colorado. p. 12. ISBN   9781607320852.
  6. Reiter, Marshall (1 March 2008). "Geothermal anomalies in the crust and upper mantle along Southern Rocky Mountain transitions". GSA Bulletin. 120 (3–4): 439. doi:10.1130/B26198.1. ISSN   0016-7606.
  7. E., Karlstrom, K.; D., Coblentz, D.; B., Ouimet, W.; E., Kirby; W., van Wijk, J.; B., Schmandt; J., Crossey, L.; R., Crow; S., Kelley (December 2009). "Dynamic uplift of the Colorado Rockies and western Colorado Plateau in the last 6 Ma driven by mantle flow and buoyancy: Evidence from the Colorado River region". AGU Fall Meeting Abstracts. 2009: T51F–04. Bibcode:2009AGUFM.T51F..04K.
  8. A., Darling; K., Karlstrom; E., Kirby; W., Ouimet; D., Coblentz; A., Aslan (2008). "Evaluating Neogene Uplift and Denudational History of the Colorado Rockies Using River Profiles and Incision Records". AGU Fall Meeting Abstracts. 2008: T11C–1893. Bibcode:2008AGUFM.T11C1893D.
  9. M., Sandoval; D., Coblentz; K., Karlstrom; A., Sussman (2005). "Connecting Topographic Analysis With Colorado River Incision History: Sensitive Gauges of Neotectonics in the Rocky Mountains". AGU Fall Meeting Abstracts. 2005: T23C–0580. Bibcode:2005AGUFM.T23C0580S.
  10. 1 2 3 K., MacCarthy, J.; C., Aster, R.; M., Hansen, S.; C., Stachnik, J.; G., Dueker, K.; E., Karlstrom, K. (2009). "Joint inversion of teleseismic body wave residuals and Joint Inversion of Teleseismic Body Wave Residuals and Bouguer Gravity Data to Constrain the Origin of the Colorado Rockies". AGU Fall Meeting Abstracts. 2009: S13B–1745. Bibcode:2009AGUFM.S13B1745M.
  11. "GEO AND THERMOCHRONOLOGICAL EVICENDE FOR THE EMPLACEMENT AND EXHUMATIONAL HISTORY OF THE TWIN LAKES BATHOLITH: IMPLICATIONS FOR THE LARAMIDE OROGENY". gsa.confex.com. Retrieved 2018-04-08.
  12. 1 2 Dueker, Yuan & Zurek 2001, p. 7.
  13. 1 2 Karlstrom et al. 2005, p. 425.
  14. Dueker, Yuan & Zurek 2001, p. 8.
  15. Karlstrom et al. 2005, p. 429.

Sources

  • Dueker, Ken; Yuan, Huaiyu; Zurek, Brian (2001). "Thick-Structured Proterozoic Lithosphere of the Rocky Mountain Region". GSA Today. 11 (12): 4. doi: 10.1130/1052-5173(2001)011<0004:TSPLOT>2.0.CO;2 .
  • Karlstrom, Karl E.; Whitmeyer, Steven J.; Dueker, Ken; Williams, Michael L.; Bowring, Samuel A.; Levander, Alan R.; Humphreys, E. D.; Keller, G. Randy; Group, CD-ROM Working (2005). "Synthesis of results from the CD-ROM Experiment: 4-D image of the lithosphere beneath the Rocky Mountains and implications for understanding the evolution of continental lithosphere". The Rocky Mountain Region: An Evolving Lithosphere Tectonics, Geochemistry, and Geophysics. Geophysical Monograph Series. 154. American Geophysical Union (AGU). pp. 421–441. doi:10.1029/154gm31. ISBN   978-0-87590-419-1.
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