Keilir Explained

Keilir
Elevation:397m (1,302feet)
Elevation Ref:[1]
Location:Reykjanes Peninsula, Iceland
Map:Iceland
Coordinates:63.9425°N -22.1708°W
Coordinates Ref:[2]
Type:Subglacial mound or tuya
Volcanic Arc/Belt:Reykjanes Volcanic Belt
Last Eruption:Pleistocene
Easiest Route:from ENE

Keilir (in Icelandic pronounced as /ˈcʰeiːlɪr̥/; 378 m asl) is a Pleistocene subglacial mound or perhaps a conical tuya[3] on Reykjanes Peninsula in Iceland.[4] Basal area is 0.773 km2, summit area 0.004 km2, basal width 0.99 km, summit width 0.07 km, volume 0.0362 km3.[3]

It is located within the area of Krýsuvík volcanic system[5] and Reykjanesfólkvangur. It is about 17 miles southwest of the capital city Reykjavík,

In March 2021 the mountain began to emit earthquakes followed by a fissure lava eruption further southwest at Fagradalsfjall.

Formation

Keilir was formed during a subglacial fissure eruption which concentrated in the end at one vent.[6] Except the cone, also some small subglacially formed hills to the north are results of this eruption.[7] [6]

Eruptions under the Weichselian glaciers on Reykjanes Peninsula

When stratigraphy is considered in detail, it tells about the different parts of this eruption: The eruption thawed the glacier ice and formed a subglacial lake in which the volcano continued to develop. The water very soon touched the magma within the vent and caused explosive activity. Tephra set down in layers into the subglacial lake. With time, the tephra built up a hill and small elongated mountain over the vent(s). When such an eruption is continued over a longer time span, the water in the end does not reach the vent(s) any more and lava begins to flow.[6]

In the top region of Keilir, there is a small cap of lava (area of lava cap 0,020 km2[3]) which could mean that the volcanic mountain is a tuya (the lava being from subaerial eruptions at the end of the eruption series)[3] or perhaps just represents a volcanic plug (the lava cooled and plugged up the vent).[6]

Ice thickness and more exact time of eruption in the case of Keilir are not known, just that it took place during the Pleistocene (Weichselian).[6]

Comparison to an Antarctic subglacial tuff cone

Smellie and other scientists newly discovered a similar monogenetic subglacial tuff cone within the ice of Antarctica and could determine the thickness of ice which covered the vent during eruption. The Antarctic cone did lie under a polar ice sheet and not a temperate glacier as was the case with Keilir. Additionally, the Antarctic cone is much older (around 640 000 years), whereas Keilir is up to 100 000 years old. And the tuff cone from Victoria Land, Antarctica, is placed next to known granitic plutonic complexes and seems to be a parasitic cone of a stratovolcano, whereas Keilir is located adjacent to presently active volcanic systems and looks as if it were placed on top of the shield volcano Þráinskjöldur, though the last one is younger than the subglacial formation. Interestingly, similar tectonics, rift zones, are behind both expressions of volcanism: the West Antarctic Rift System on the one hand,[8] and in the case of Keilir the Reykjanes Rift as part of the rift zones crossing Iceland. Also similar are their rocks – mafic lapilli tuff (in Icelandic: móberg).[8] [9]

Landmark

As the mountain is easily recognized from afar, eg. from Reykjavík, but also from sea, it was used as a landmark by fishermen and seamen for many centuries.[4]

Hiking

There is a hiking trail leading up on the mountain from ENE. At the top, a guestbook can be found within a box.[7]

An excellent view over a big part of Reykjanes Peninsula and Faxaflói is to be expected from the top in good weather.[7]

See also

Notes and References

  1. Ari Trausti Guðmundsson, Pétur Þorsteinsson: Íslensk fjöll. Gönguleiðir á 152 tind. Reykjavík 2004, p. 156
  2. https://core.ac.uk/download/pdf/52483246.pdf G.B.M.Pedersen, P. Grosse: Morphometry of subaerial shield volcanoes and glaciovolcanoes from Reykjanes Peninsula, Iceland: Effects of eruption environment. Journal of Volcanology and Geothermal Research 282, (2014), 115-133.
  3. https://core.ac.uk/download/pdf/52483246.pdf G.B.M.Pedersen, P. Grosse: Morphometry of subaerial shield volcanoes and glaciovolcanoes from Reykjanes Peninsula, Iceland: Effects of eruption environment. Journal of Volcanology and Geothermal Research 282, (2014), 115-133.
  4. Íslandshandbókin. Náttúra, saga og sérkenni. Reykjavík 1989, p. 53
  5. See eg. maps herein: Ermias Yohannes Berhane: Geochemical interpretation of thermal water and gas samples from Krýsuvík, Iceland and Alid, Eritrea. The United Nations University. Report No. 18, 2004.
  6. Snæbjörn Guðmundsson: Vegavísir um jarðfræði Íslands. Reykjavík 2015, p. 22-23
  7. Ari Trausti Guðmundsson, Pétur Þorsteinsson: Íslensk fjöll. Gönguleiðir á 152 tind. Reykjavík 2004, p. 156-157
  8. https://link.springer.com/article/10.1007/s00445-017-1185-x J. L. Smellie, etal.: A tuff cone erupted under frozen-bed ice (northern Victoria Land, Antarctica): linking glaciovolcanic and cosmogenic nuclide data for ice sheet reconstructions. (2017).
  9. https://skemman.is/bitstream/1946/7449/1/Ritgerdin_lokaeintak_ias.pdf Helgi Páll Jónsson: Eldfjallagarður og jarðminjar á Reykjanesskaga. MS ritgerð. Leiðbeinendur Ólafur Ingólfsson, prófessor. Jarðvísindadeild Verkfræði- og náttúruvísindasvið Háskóli Íslands. (2011)