Cabezon Peak

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Cabezon Peak
Cabezon Peak reflection.jpg
Cabezon Peak at sunrise
Highest point
Elevation 7,785 ft (2,373 m) [1]
Prominence 1,508 ft (460 m) [1]
Parent peak Pt 9114 [2]
Isolation 10.35 mi (16.66 km) [2]
Coordinates 35°35′58″N107°05′45″W / 35.5994727°N 107.0958761°W / 35.5994727; -107.0958761 [3]
Geography
USA New Mexico relief location map.svg
Red triangle with thick white border.svg
Cabezon Peak
Location in New Mexico
Usa edcp relief location map.png
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Cabezon Peak
Cabezon Peak (the United States)
Location Sandoval County, New Mexico, US
Parent range Colorado Plateau
Topo map USGS Cabezon Peak
Geology
Type of rock basalt
Climbing
Easiest route class 3+ scrambling [2]

Cabezon Peak is a large volcanic plug that is a prominent feature in northwestern New Mexico. It rises to 7,785 feet (2,373 meters) in elevation, and nearly 2,000 feet above the floor of the Rio Puerco Valley. [4] Cabezon Peak is two miles south of the old ghost town of Cabezon and the Rio Puerco. This volcanic neck is formed of basalt and is part of the Mount Taylor volcanic field. A volcanic neck or plug is formed when magma from an existing volcano solidifies in the pipe or neck and the surrounding sediment is eroded away. [5] Marine Cretaceous rocks of the Mancos Shale and Point Lookout Sandstone are exposed around the base of Cabezon Peak.

Contents

Cabezon means “big head” in Spanish. This stems from a Navajo myth which holds that it is the head of the giant Ye’i-tsoh after being slain by the twins Nayenezgani and To’badzistsini. [6] The first geologist to study Cabezon Peak was likely Clarence E. Dutton, who also photographed the peak in 1884–1885. [7] Further studies were carried out by Douglas Wilson Johnson in 1907 [8] and C.B. Hunt in 1938. [9] All identified the peak as an exhumed volcanic neck. [7]

Mesa Prieta is south of Cabezon Peak.

Geology

Cabezon Peak is the solidified core of a volcano that erupted 2.658 ± 0.032 million years ago, based on argon-argon dating. The eruption at this volcano likely began with lava fountains from the vent, which built up a scoria cone. Lava later ponded in the interior of the cone, solidifying into a massive plug. Erosion then stripped away the less resistant scoria, leaving the highly resistant plug visible today. [10]

The visible plug is nearly cylindrical in shape; it is approximately 0.5 kilometers (0.3 mi) across at its base, and tapers to 0.15 kilometers (0.1 mi). The plug is composed mostly of basalt columns, about 0.5 to 2.5 meters (1.6 to 8.2 ft) in diameter, that are vertical in the upper part of the plug but splay outwards at its base. The topmost part of the plug is scoria that remains from the original cone. [11]

The lava erupted at Cabezon Peak was alkaline basalt in composition; [12] that is, a lava relatively low in silica, and moderately enriched in alkali metals. The basalt that solidified from this lava contains visible crystals (phenocrysts) of olivine, clinopyroxene, plagioclase feldspar, and magnetite in a very fine-grained matrix. The origin of the alkaline basalt is uncertain. It may have formed in the upper mantle where hot rock crept upwards beneath the Rio Grande rift. [13]

The basalt of Cabezon Peak contains a small number of xenoliths, fragments of solid rock that were entrained in the magma from the upper mantle or lower crust. [14]

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References

  1. 1 2 "Cabezon Peak, New Mexico". Peakbagger.com.
  2. 1 2 3 "Cabezon Peak - 7,785' UT". listsofjohn.com. Retrieved 2020-09-26.
  3. U.S. Geological Survey Geographic Names Information System: Cabezon Peak
  4. "Cabezon Peak Wilderness Study Area". Archived from the original on 2010-05-28. Retrieved 2010-06-26.
  5. Hallett, C. Bruce (1992). "Volcanic geology of the Rio Puerco necks" (PDF). New Mexico Geological Society Field Conference Series. 43: 135–144. Retrieved 17 June 2021.
  6. Locke, R. F. (1990) Sweet Salt: Navajo folktales and mythology, Roundtable Publishing Company, Santa Monica
  7. 1 2 Hallett 1992, pp. 1369.
  8. Johnson, D. W. (1 January 1907). "Volcanic necks of the Mount Taylor region, New Mexico". Geological Society of America Bulletin. 18 (1): 303–324. doi:10.1130/GSAB-18-303.
  9. Hunt, C.B. (1938). "Igneous geology and structure of the Mount Taylor volcanic field, New Mexico". U.S. Geological Survey Professional Paper. Professional Paper. 189-B. doi: 10.3133/pp189B .
  10. Hallett 1992, pp. 135, 139.
  11. Hallett 1992, pp. 140.
  12. Hallett 1992, pp. 136.
  13. Hallett 1992, pp. 137.
  14. Hallett 1992, pp. 139.

Further reading

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