1996 eruption of Gjálp explained

1996 eruption of Gjálp
Start Date:30 September 1996
End Date:13 October 1996
Coordinates:[1]
Vei:3
Impact:Jökulhlaup over Skeiðarársandur, Hringvegur partially destroyed

Gjálp (in Icelandic pronounced as /ˈcaul̥p/) is a hyaloclastite ridge (tindar) in Iceland under the Vatnajökull glacier shield. Its present form resulted from an eruption series in 1996 and it is probably part of the Grímsvötn volcanic system.[2] [3] However not all the scientists were of this opinion, as seismic studies are consistent with a lateral dike intrusion at about depth from Bárðarbunga being the trigger event. This does not exclude a shallower secondary intrusion from Grímsvötn being important in the subaerial eruption itself.[4]

Importance

The eruption was of importance, because it was for the first time that a subglacial eruption under a thick ice cover as well as the connected jökulhlaup could be observed and analyzed by modern technique.[5] [6]

Geography

Eruption location

The subglacial eruption fissure is to be found in the northwest corner of Vatnajökull ice cap more or less halfway between the central volcanoes Bárðarbunga and Grímsvötn.[7] It is also to the west of the Hamarinn central volcano of the Bárðarbunga volcanic system which has the Loki Ridge extending west-east which has been assigned historically to the Loki-Fögrufjöll volcano.[8]

Vatnajökull ice cap

The Vatnajökull glacier which covered the location at time of eruption had a thickness of . In other places the glacier shield can have thicknesses of up to . Vatnajökull covered an area of in 1996,[9] but it is retreating and measured just in 2007.[10] The glacier is temperate, lies in lower elevations and is therefore sensible to climatic changes. As a consequence it has been advancing and retreating since the Weichselian glaciation. Its last advance took place during the so called Little Ice Age from the 13th to the end of the 19th century and since then it is retreating.[10]

Parts of two volcanic zones of Iceland are placed under Vatnajökull, ie. the very active East Volcanic Zone (connected to rifting at the divergent plate boundary in Iceland[10]), responsible for the highest number of eruptions after deglaciation[11] and with the mantle plume probably under Bárðarbunga, ie. under Vatnajökull.[12] "More than 80 eruptions occurred during the last 800 years in Vatnajökull."[13] There is also the much less active Öraefi Volcanic Belt, a flank zone mostly under the eastern part of Vatnajökull.[10] [14] It is thought that due to climate change, Vatnajökull has lost about 10% of its mass since the end of the 19th century. Measurements showed an accentuated and even accelerating rate of glacio-isostatic uplift.[12] This could lead to increased magma production (so called decompression melt production), because the "pot lid" formed by the glaciers and their weight will be absent in the future, and eruption frequency could increase as a consequence.[15]

The region of the Gjálp fissures is part of this active East Volcanic Zone under Vatnajökull.

Geology

The Gjálp eruption formed in about two weeks a subglacial hyaloclastite ridge, also called tindar by some geologists, in a zone of known former eruptions. Predominantly basaltic andesite was erupted to a volume of DRE.

The eruption in 1996

Precursors and possible connection between volcanic systems

Some large earthquakes (M5+) had taken place in the central volcano Bárðarbunga just before the eruption and proved to be precursors of the eruptive events. In particular a event took place on the 29th September in the northern part of the Bárðarbunga caldera and its aftershock sequence propagated over the next two days in a linear fashion towards Grímsvötn.[16] It is possible that the first large event was associated with a subglacial eruption within the Bárðarbunga caldera a couple of days before the Gjálp eruption. The seismological study sees a parallel to the 2014–2015 eruptions and to the caldera drop in Bárðarbunga central volcano in that eruption, and postulate a similar magma migration to the eruption site though on a smaller scale. This could mean that the volcano is part of the fissure system of Bárðarbunga, not Grímsvötn. There had been seismic studies that suggested an east west line of seismic activity in the Bárðarbunga volcanic system at the Loki Ridge intersected the eruption location,[17] but the Loki Ridge was not seismically active during the eruption.

Another possibility is that Bárðarbunga magma entered a portion the magmatic system of Grímsvötn and started the eruption by this intrusion. Bárðarbunga is known for such tendencies, as its magma mingled with Torfajökull magma at least three times in the past which resulted in bimodal eruptions, e.g. of the Veiðivötn and at Landmannalaugar by the end of the 15th century.[18]

Formation of the tindar volcano

The Gjálp eruption took place at a some kilometers long known fissure under of glacier ice within Vatnajökull. The eruption in October 1996 could push through this ice in about 30 hours[2] and took place from 30 September to 13 October 1996. The eruption fissure had a length of .[7]

The location is some kilometers to the north of Grímsvötn caldera.[2]

In the beginning, a long N–S trending depression was formed above the fissure, with time three ice cauldrons were built at each end and in the middle,[7] but the eruption concentrated later on one of them where a wide crater came to light. After some time, an open ice canyon was built above the fissure. It had a length of about and was up to in width.[2]

The meltwater drained first through the ice canyon and then disappeared into subglacial channels and run from there to the subglacial caldera lake of Grímsvötn.[2] The subglacial channels were easily recognized, because continuous melting caused by the hot water from the eruption site initiated the formation of depressions on the ice surface. And so the scientists followed the melting path down to Grímsvötn caldera.[7]

Though the eruption was mostly explosive, the ash was not expelled far from the vents, but fell back into the canyon. The quantity of eruption products stayed more or less the same the whole time which was explained by ice flow into the crater.[2]

During the two weeks of eruption, volcanic activity thawed no less than of ice, and this continued to a lesser extent for some time after the end of the eruption.[2]

The newly formed tindar disappeared again completely under the glacier ice about 1 year later,[2] but an identifiable ice cauldron remained until at least 2007. The tindar was a long ridge newly deposited to a height of above the pre-existing bedrock with a volume of . It is postulated that the original unconsolidated hyaloclastitic volcanic glass and tephra of the ridge could have by now undergone a process called palagonitization due to hydrothermal alteration, to palagonite, a consolidated rock more resistant to erosion, but it is unknown if this has happened.

Eruption products

The eruptive products consisted of predominantly basaltic andesite which surprised the scientists as these more evolved rocks are neither typical for Bárðarbunga nor for Grímsvötn, both more connected to basaltic volcanism. Some scientists thought therefore that Gjálp could be an independent volcano.[9] The bulk samples obtained shortly after the eruption ranged from basaltic andesite to basalt and were of distinctive Grímsvötn composition.[19] Basaltic andesite from a 1887 eruption had been previously attributed to the Grímsvötn volcanic system and had very similar composition. Tephra assigned to the eruption has been analysed by several researchers and has composition that is Grímsvötn basaltic andesite with rarely Grímsvötn basalt. A total of three samples out of the several hundred in the literature had some tephra with Bárðarbunga basalt composition. It is unknown if this was due to contamination from pre-existing tephra layers in the ice that was overlying Gjálp or if the Bárðarbunga basalt was erupted together with the Grímsvötn basaltic andesite.

Jökulhlaup in 1996

In the beginning, scientists presumed that the eruption would be followed immediately by a big jökulhlaup (a sort of a meltwater tsunami including large blocks of ice and a high quantity of sediment). But it took some time to fill the subglacial lake of Grímsvötn in such a manner that the ice wall holding it back would break.[2]

Not before some weeks had passed after the eruption was terminated, did the expected jökulhlaup happen. This was from 4 to 7 November 1996.[9] The melt water streamed mostly in subglacial channels and in the end under the outlet glacier Skeiðarárjökull. There, to everybody's surprise, the water masses streamed in such a quantity that the whole glacier was lifted up.[20] [21]

In the end, the water sprang up from under the glacier edge and the flood covered most of Skeiðarársandur glacial outwash plain, destroying on its way large parts of the main road Hringvegur including two bridges and some communication installations. Luckily, the road had been closed before the flood so that nobody was injured.

The volume of melt water produced by this eruption was around .[22] Over the sandur streamed up to .[2] The first estimates had been somewhat lower.[9]

Former eruption in 1938

At more or less the same place another eruption had taken place in the 1930s. It had also caused a jökulhlaup, but at the time, science could not yet analyse the events. That eruption stayed subglacial.[2]

See also

Further reading

Notes and References

  1. Jarosch. A.. Gudmundsson. M.T.. Högnadóttir. T.. Axelsson. G.. 2008. Progressive cooling of the hyaloclastite ridge at Gjálp, Iceland, 1996–2005. Journal of Volcanology and Geothermal Research. 170. 3-4. 218-229. 10.1016/j.jvolgeores.2007.10.012. 2008JVGR..170..218J.
  2. Snæbjörn Guðmundsson: Vegavísir um jarðfræði Íslands. Reykjavík 2015, p. 280-281
  3. See also Retrieved 29 August 2020.
  4. Konstantinou. K.I.. Utami. I.W.. Giannopoulos. D. Sokos. E.. 2019. A reappraisal of seismicity recorded during the 1996 Gjálp eruption, Iceland, in light of the 2014–2015 Bárðarbunga–Holuhraun lateral dike intrusion. Pure and Applied Geophysics. 177. 6. 2579-2595. 10.1007/s00024-019-02387-x. 2019PApGe.177.2579K.
  5. The 1996 eruption at Gjálp, Vatnajkull ice cap, Iceland: efficiency of heat transfer, ice deformation and subglacial water pressure. Magnús T.. Gudmundsson. Freysteinn. Sigmundsson. Helgi. Björnsson. Thordís. Högnadóttir. Bulletin Volcanology. 2004. 66. 46–65. 10.1007/s00445-003-0295-9.
  6. See also: Will subglacial rhyolite eruptions be explosive or intrusive? Some insights from analytical models. Hugh . Tuffen. D.W.. McGarvie. Gilbert. J.S.. Annals of Glaciology. 2007. 45. 87-94. 30 August 2020. 10.3189/172756407782282534.
  7. Glacier–volcano interactions deduced by SAR interferometry. Björnsson. H.. Rott. H.. Gudmundsson. S.. Fischer. A.. Siegel. A.. Gudmundsson. M.T.. 2001. Journal of Glaciology. 47. 156. 58-70. 8 August 2020. 10.3189/172756501781832520. 2001JGlac..47...58B.
  8. Björnsson. H.. Einarsson. P.. 1990. Volcanoes beneath Vatnajökull, Iceland: Evidence from radio echo-sounding, earthquakes and jökulhlaups. Jökull. 40. 147-168. live. https://web.archive.org/web/20230320235442id_/https://jokull.jorfi.is/articles/jokull1990.40/jokull1990.40.147.pdf. 20 March 2023. 25 March 2024.
  9. Center of Icelandic Hotspot experiences Volcanic Unrest. P.. Einarsson. Bryndis. Brandsdottir. Magnus Tumi. Gudmundsson. Helgi. Bjornsson. Karl. Gronvold. Freysteinn. Sigmundsson. Eos, Transactions American Geophysical Union. 78. 35. 2 September 1997. 29 August 2020. 10.1029/97EO00237. 1997EOSTr..78..369E. 369-375.
  10. Glacio‐isostatic deformation around the Vatnajökull ice cap, Iceland, induced by recent climate warming: GPS observations and finite element modeling. C.. Pagli. Sigmundsson. F.. Lund. B.. Sturkell. E.. Geirsson. H.. Einarsson. P.. Árnadóttir. T.. Hreinsdóttir. S.. 2007. Journal of Geophysical Research: Solid Earth. 112. B8. 10.1029/2006JB004421. 8 August 2020. 11568/500513. free.
  11. Postglacial volcanism in Iceland. Thorvaldur. Thordarson. Ármann . Höskuldsson. Jökull. 58. 2008. 24 March 2024.
  12. Hildur María. Friðriksdóttir. Landris á Vatnajökulssvæðinu metið með GPS landmælingum. BS ritgerð. Jarðvísindadeild Háskóli Íslands. Leiðbeinendur Sigrún Hreinsdóttir, Erik Sturkell.. 2017. 24 March 2024. is.
  13. Subglacial lakes and jökulhlaups in Iceland. Helgi. Björnsson. Global and Planetary Change. 35. 2002. 255–271. 31 August 2020. 10.1016/S0921-8181(02)00130-3. 2003GPC....35..255B.
  14. See also: Volcanoes beneath Vatnajökull, Iceland. Evidence from radio echo sounding, earthquakes and jökulhlaups. Helgi. Björnsson. Páll. Einarsson. Jökull. 40. 1990. 8 August 2020.
  15. See eg.: Effects of present‐day deglaciation in Iceland on mantle melt production rates. Schmidt. P.. Lund. B.. Hieronymus. C.. Maclennan. J.. Árnadóttir. T.. Pagli. C.. Journal of Geophysical Research: Solid Earth. 118. 7. 3366-3379 . 10.1002/jgrb.50273. 2013. 4 September 2020. 11568/500303. free.
  16. zh. A reappraisal of seismicity recorded during the 1996 Gjalp eruption in Iceland using modern seismological methods. PhD dissertation . National Central University, Taiwan (國立中央大學). 2018. Utami. I.W. . 24 March 2024.
  17. Seismicity in Iceland: 1994–2007.. Jakobsdóttir. S.S.. 2008. Jökull. 58. 1. 75–100.
  18. Zellmer. G.F.. Rubin. K.H.. Grönvold. K.. Jurado-Chichay. Z.. 2008. On the recent bimodal magmatic processes and their rates in the Torfajökull–Veidivötn area, Iceland.. Earth and Planetary Science Letters. 269. 3-4. 388-398. 10.1016/j.epsl.2008.02.026. 2008E&PSL.269..388Z.
  19. The tephra layer formed in the 1996 eruption of Gjálp: Dispersal and volume. Magister Scientiarum thesis. Irma Gná. Jóngeirsdóttir. 2022. Faculty of Earth Science School of Engineering and Natural Sciences, University of Iceland.
  20. Propagation of a subglacial flood wave during the initiation of a jôkulhlaup. Tomas. Jóhannesson. Hydrological Sciences-Journal-des Sciences Hydrologiques. 47. 3. 2002. 8 August 2020.
  21. See also: Helgi. Björnsson. Understanding jökulhlaups: from tale to theory. Journal of Glaciology. 56. 200. 2010. 8 August 2020.
  22. Volcanic hazards in Iceland. M.T.. Gudmundsson. G.. Larsen. Á.. Höskuldsson. Á.G.. Gylfason. Jökull. 58 . 2008. 8 August 2020.