Cobb hotspot explained

The Cobb hotspot is a marine volcanic hotspot at (46˚ N, 130˚ W),[1] 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–Eickelberg Seamount chain. The hotspot is currently collocated with the Juan de Fuca Ridge.

Cobb Seamount chain

See main article: Cobb Seamount. The Cobb hotspot has created an underwater mountain range that extends to the northwest and ends at the Aleutian Trench. The oldest mount in the chain is the Marchland Seamount, at 30 to 43 Ma (million years old). The old, northwestern end of the chain collides with a subduction zone; therefore, the true age of the hotspot is difficult to determine as the oceanic crust is being consumed.[2] Axial Seamount is the hotspot's most recent eruptive center, which last erupted in 2015, 2011 and 1998.[3] [4] The central ridge of the hotspot is thicker than the surrounding crust by a few kilometers and may be accumulated buildup from the magma released at the hotspot, which is essentially a submarine volcano with a root 20kmto40kmkm (10milesto30mileskm) in diameter, reaching a depth of beneath the volcano. The magma flows at a rate of . The caldera is below sea level.[5] [6]

Geochemistry

Hotspots are formed when magma from the lower mantle upwells to the crust of Earth and breaks through the surface crust, whether that be oceanic crust or continental. This movement of magma breaks through the upper mantle, or the lithosphere, and creates a volcanic spot. This does not mean that all volcanoes are hotspots; some are created through interactions at plate boundaries. Tectonic plates move over hotspots creating a chain of volcanically-formed mountains over time. This is supported by the theory of plate tectonics. The peaks and mountains left behind are no longer active volcanoes. Hotspots do not necessarily occur on a plate boundary, though the Cobb Hotspot does.[7]

Comparisons with mid-ocean ridge basalts

The magmas from the spreading ridge and the hotspot have differences. For one, they contain dissimilar concentrations of elements like Na2O, CaO and Sr at a given mafic level. This difference highlights that the magmas were formed at different depths in the mantle. It is theorized that the hotspot magma was melted deeper than that of the ridge. For these two masses of magma to exist, the temperature of the magma at the Cobb Hotspot must be of a particularly high temperature.[8] [9] It is undetermined whether the hotspot was created from mantle-core boundary convection, as the end of the chain is subducting under another. The initial plume of magma would leave behind geologic evidence at the surface, but due to the consumption of the older end of the chain this evidence isn't visible.

Variations along the chain

Trace elements were used to discover that older mounts created by the Cobb Hotspot contained more minerals like olivine and augite; both mafic minerals. Younger mounts created by the hotspot contain more minerals like calcic plagioclase, augite and pigeonite; they contain little to no olivine. These characteristics found at the younger mounts are like those found in basalts recovered from the Juan de Fuca Ridge.[10] It is inferred that much of the difference in basalt composition along the chain is due to the time-dependent distance between hotspot and ridge. Oceanic crust thickens with distance from the mid-ocean ridge at which it originated. Therefore, as the Pacific plate migrated, the magma from the Cobb hotspot interacted with different thicknesses of crust. A thicker ocean crust would result in more differentiated basalt, while thinner crusts, like those at the current hotspot location, create less differentiated magma.[11]

Interaction of the Cobb hotspot and the Juan de Fuca Ridge

The magma supply to the Cobb hotspot is more primitive than that of the Juan de Fuca Ridge magma. As the archaic magma flows beneath the magma chamber of the ridge, it causes further melting and rapid cooling, which allows for fractional crystallization.[6] [9]

See also

References

46°N -130°W

Notes and References

  1. Web site: GPS coordinates of Cobb hotspot, United States. Latitude: 46.0000 Longitude: -130.0000. Latitude.to. Latitude.to, maps, geolocated articles, latitude longitude coordinate conversion.. en. 2017-05-05.
  2. Keller. R.. Fisk. M.. Duncan. R.. Rowe. M.. Russo. C.. Dziak. R.. 2003-12-01. Cobb Hotspot Volcanism Prior to 7 Million Years ago. 2003AGUFM.V32A1002K. AGU Fall Meeting Abstracts. 32. V32A–1002.
  3. Chadwick. J.. Perfit. M.. Embley. B.. Ridley. I.. Jonasson. I.. Merle. S.. 2001-12-01. Geochemical and Tectonic Effects of the Interaction of the Cobb Hotspot and the Juan de Fuca Ridge. 2001AGUFM.T31D..02C. AGU Fall Meeting Abstracts. 31. T31D–02.
  4. Web site: Axial Seamount - Hydrothermal vents. www.pmel.noaa.gov. 2017-06-04.
  5. Michael West; William Menke; Maya Tolstoy (February 2003). "Focused magma supply at the intersection of the Cobb hotspot and Juan de Fuca ridge" (PDF). Retrieved 2008-11-19.
  6. Michael West; William Menke; Maya Tolstoy. Focused Melt supply at the Cobb Hotspot/ Juan de Fuca Plate (PDF).
  7. Web site: What is a Hot Spot? Volcano World Oregon State University. volcano.oregonstate.edu. en. 2017-05-05. 2017-05-20. https://web.archive.org/web/20170520062903/http://volcano.oregonstate.edu/what-is-a-hot-spot. dead.
  8. Rhodes. J. M.. Morgan. C.. Liias. R. A.. 1990-08-10. Geochemistry of axial seamount lavas: Magmatic relationship between the Cobb Hotspot and the Juan de Fuca Ridge. Journal of Geophysical Research: Solid Earth. en. 95. B8. 12713–12733. 10.1029/JB095iB08p12713. 2156-2202. 1990JGR....9512713R.
  9. Chadwick. J. 2005. Magmatic effects of the Cobb hot spot on the Juan de Fuca Ridge. Journal of Geophysical Research: Solid Earth. 110. 1–16. 10.1029/2003jb002767. 2005JGRB..110.3101C. free.
  10. Web site: Geochemical evolution of the Cobb hotspot. gsa.confex.com. 2017-04-22.
  11. Web site: Abstract: Progressive changes in the composition of Cobb hotspot lavas due to thinning lithosphere (2012 GSA Annual Meeting in Charlotte). gsa.confex.com. 2017-06-04. 2012-11-07.