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North Arch volcanic field

Coordinates: 24°N 158°W / 24°N 158°W / 24; -158[1]
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Geography of North Arch volcanic field
Map of the North Arch volcanic field, with Oahu and sampling sites marked
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300km
200miles
South Arch volcanic field
South Arch
volcanic field
South Arch volcanic field
North Arch volcanic field
North Arch
volcanic field
Coordinates24°N 158°W / 24°N 158°W / 24; -158[1]
Area
 • Total25,000 km2 (9,700 sq mi)
 • Land0%
 • Water100%
Highest point3,900 m (12,800 ft) below sealevel[2]
Lowest point4,700 m (15,400 ft) below sealevel[3]
TerrainBasalt flow with other volcanic features such as cones

North Arch volcanic field[a] is an underwater volcanic field north of Oahu, Hawaii. It covers an area of about 25,000 square kilometres (9,700 sq mi) and consists of large expanses of alkali basalt, basanite and nephelinite that form extensive lava flows and volcanic cones. Some lava flows are longer than 100 kilometres (62 mi).

This volcanic field appears to be somehow related to the Hawaii hotspot, although the exact mechanisms are debated. Similar volcanic units are also found on the adjacent islands, such as the Honolulu Volcanics on Oahu. The volcanic field was formed through effusive and explosive eruptions between 1.5 and 0.5 million years ago, although eruptions before and after these dates also took place.

Geography and geomorphology

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The North Arch volcanic field lies 200–400 kilometres (120–250 mi)[5] north of Oahu at 3,900–4,380 metres (12,800–14,370 ft) depth;[2] within the Exclusive Economic Zone of the Hawaiian Islands. The existence of lava flows in this geological region was already postulated in 1964, but it was GLORIA sidescan sonar eventually identified an anomalously reflective seafloor that constitutes the North Arch volcanic field;[6] the discovery was first published in 1968[7] and rock samples taken in 1988.[6] The volcanic field lies on the Hawaiian Arch[b][2] and on its southern slope.[10]

The volcanic field covers an area of about 25,000 square kilometres (9,700 sq mi)[2][c] and consists of about 100 observed volcanic cones with associated lava flows. The volcanic cones range from shield-like to steep[11] to lava dome-like and long ridges[12] and lava flows range from lava lakes forming flat-topped cones[10] to over 100 kilometres (62 mi) long lava flows despite the flat terrain;[11] small hills in the lava flows may be vents.[8] The average thickness of the lava flows probably amounts to either less than 10 metres (33 ft)[13] or about 40–50 metres (130–160 ft).[14] Fissure vents also occur in the field; one of these has been the source of a 3,600 square kilometres (1,400 sq mi) lava flow.[15] Owing to the sizes of the lava flows, the field has also been called a flood basalt in analogy to its usually much larger continent-based counterparts.[4] The volcanoes are located among Cretaceous seamounts and sediment-covered seafloor, which forms kipukas between the lava flows.[16] In turn, lava flows are covered with over 1 metre (3 ft 3 in) thick sediments.[8] A noticeable swell where clusters of volcanic cones occur may reflect the presence of sills.[10] The total volume of the volcanic field is about 1,250–1,000 cubic kilometres (300–240 cu mi),[16] much less than a typical Hawaiian shield stage volcano,[17] and rocks occur in the form of e.g. glass shards, pillow lavas, scoria and volcaniclastic material.[11] A seismic velocity anomaly at depth appears to be associated with the North Arch volcanic field.[18][19]

Geology

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The bulk of the volcanism of a Hawaiian volcano is made up by the shield stage during which tholeiitic lavas are erupted.[20] This stage is after between 250,000 – 2,500,000 years followed by a "post-erosional" or "rejuvenated" stage during which lavas of alkali basalt, melilitite and nephelinite composition; such volcanism has been observed on Koolau, Kauai and Niihau[2] and covers large parts of the Hawaiian Islands even though it makes up less than one percent of their volume.[1] The North Arch volcanic rocks resemble the composition of these rejuvenated stage volcanics of Hawaii such as the Honolulu Volcanics,[21] and another unit of these volcanics forms the South Arch volcanic field[20] 200 kilometres (120 mi) south of Kilauea,[22] and have been deemed "peripheral lavas" of the Hawaii hotspot.[23] In fact, it has been proposed that the rejuvenated volcanics of Niihau, Kauai, Oahu and Molokai might actually be part of the North Arch volcanic field.[24] Other volcanic units of a probably similar nature have been found between Oahu and Kauai.[25]

Origin

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While the shield stage volcanics of Hawaii are linked to the mantle plume, the origin of volcanism in the North Arch volcanic field is debated:[1]

The volcanism of the North Arch volcanic field might nevertheless have a common cause as the rejuvenated stage volcanism of Hawaiian Islands.[13] Volcanic units interpreted similarly to the North Arch volcanic field are also known from Kerguelen.[30]

Composition

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Samples taken from the North Arch volcanic field are fine grained or glassy[31] with varying quantities of vesicles[32] and consist of alkali basalt, basanite[31] and nephelinite,[21] with variable chlorine, magnesium, potassium and sulfur contents.[33] Olivine is the most important phenocryst, although clinopyroxene[34] and spinel are also found.[35] This diverse composition stems from variable melting from a common source rock with subsequent fractionation of olivine[36] and garnet;[37] the source rock appears to be ultimately a product of both mantle and mantle plume components.[38] Hyaloclastite is also found;[8] clay and palagonite found in the field may have formed from volcanic ash[39] through e.g. hydrothermal alteration[32] and manganese oxide crusts cover many flows.[8]

Eruption history

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Volcanism on the North Arch volcanic field occurred during the Plio-Pleistocene[16] between 1.5 million years ago[d] and less than 500,000 years ago, at the same time as the Honolulu Volcanics[1] although even younger flows have been found.[15] The timing of volcanic activity has been inferred from the thicknesses of palagonite and sediment layers as well as the stratigraphy[8] and overlaps with rejuvenated volcanism on Oahu, Kauai and Niihau.[9] In contrast, the South Arch volcanic field was emplaced in the last 10,000 years.[41]

Apparently the central part of the field was emplaced first, with the surrounding parts forming later; in addition, lava flows which make up the surrounding parts appear to preferentially originate at the foot of Cretaceous ridges and seamounts;[42] perhaps these ridges and seamounts can act as pathways for magma to reach the surface.[43] Total magma production is about 0.001 cubic kilometres per year (0.00024 cu mi/a).[44]

The North Arch volcanic field has been the site of voluminous lava effusion[10] and the formation of shallow magma chambers which gave rise to pit craters when they collapsed.[15] Despite the great depth of the North Arch volcanic field, traces of explosive eruptions has been found there[16] such as steep and low volcanic cones and deposits from fire fountaining;[45] the formation of bubbles from volatile substances in the magma[45] and processes involving supercritical fluids and magma-water interaction are probably involved in the explosive volcanism there.[46]

Notes

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  1. ^ The name is a reference to this position and also to differentiate it from the South Arch volcanic field.[4]
  2. ^ The Hawaiian Arch is a 0.2 kilometres (0.12 mi) high ridge that formed through the flexure induced by the weight of the Hawaiian Islands[8] and is accompanied by a trough.[9]
  3. ^ In turn, it appears to be part of an even larger field that covers 150,000 square kilometres (58,000 sq mi).[7]
  4. ^ One eruption may have occurred over 1.6 million years ago[8] and some flows are buried beneath sediments generated by the 1.8 – 2.7 million years old Nuanuu landslide on Koolau volcano, Oahu.[40]

References

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  1. ^ a b c d e Clague, Frey & Yang 2003, p. 604.
  2. ^ a b c d e Clague, Frey & Yang 2003, p. 603.
  3. ^ Pfluger 2022, Fig.4..
  4. ^ a b Clague et al. 1990, p. 176.
  5. ^ Sinton et al. 2000, p. 688.
  6. ^ a b Clague et al. 1990, p. 175.
  7. ^ a b Holcomb et al. 1989, p. 611.
  8. ^ a b c d e f g Poreda et al. 1997, p. 913.
  9. ^ a b Sinton et al. 2000, p. 668.
  10. ^ a b c d Hirano, N.; Clague, D.; Takahashi, E.; Hirata, T.; Coombs, M.; Eakins, B. (1 December 2003). "Eruptive style and geochemistry of North Arch lavas". AGU Fall Meeting Abstracts. 22: V22C–0593. Bibcode:2003AGUFM.V22C0593H.
  11. ^ a b c Davis & Clague 2005, pp. 297–298.
  12. ^ Normark et al. 1989, p. 18.
  13. ^ a b c d Herbrich, Antje; Hoernle, Kaj; Werner, Reinhard; Hauff, Folkmar; Bogaard, Paul v. d.; Garbe-Schönberg, Dieter (1 January 2015). "Cocos Plate Seamounts offshore NW Costa Rica and SW Nicaragua: Implications for large-scale distribution of Galápagos plume material in the upper mantle" (PDF). Lithos. 212–215: 228. Bibcode:2015Litho.212..214H. doi:10.1016/j.lithos.2014.10.014. ISSN 0024-4937.
  14. ^ Bianco et al. 2005, p. 19.
  15. ^ a b c Clague, David A.; Uto, Kozo; Satake, Kenji; Davis, Alicé S. (2002). "Eruption style and flow emplacement in the Submarine North Arch Volcanic Field, Hawaii". Hawaiian Volcanoes: Deep Underwater Perspectives. Geophysical Monograph Series. Vol. 128. pp. 65–84. doi:10.1029/GM128p0065. ISBN 0-87590-987-6.
  16. ^ a b c d Davis & Clague 2005, p. 295.
  17. ^ Bianco et al. 2005, p. 2.
  18. ^ Hauri, Erik H.; Bercovici, David; Detrick, Robert S.; Solomon, Sean C.; Collins, John A.; Wolfe, Cecily J.; Orcutt, John A.; Markee, Amanda; Laske, Gabi (1 December 2011). "Asymmetric shallow mantle structure beneath the Hawaiian Swell-evidence from Rayleigh waves recorded by the PLUME network". Geophysical Journal International. 187 (3): 1738. Bibcode:2011GeoJI.187.1725L. doi:10.1111/j.1365-246X.2011.05238.x. hdl:1912/4952. ISSN 0956-540X.
  19. ^ Le, Yang & Morgan 2022, p. 1.
  20. ^ a b Sinton et al. 2000, p. 667.
  21. ^ a b Davis & Clague 2005, p. 296.
  22. ^ Kani, T.; Hanan, B. B.; Kingsley, R.; Schilling, J. (1 December 2005). "Constraints on the Source Components Involved in the Magmatism of North Arch Volcanic Field and South Arch Volcanic Field, Hawaii". AGU Fall Meeting Abstracts. 51: V51A–1470. Bibcode:2005AGUFM.V51A1470K.
  23. ^ Clague et al. 1990, p. 184.
  24. ^ Uto, K.; Ishizuka, O.; Garcia, M. O.; Clague, D. A.; Naka, J. (1 December 2002). "Reconsideration of evolutionary model of the Hawaiian-type volcano: 40Ar/39Ar ages for lavas from deep interior of Oahu Island and alkali basalts from the North Arch volcanic field". AGU Fall Meeting Abstracts. 62: T62A–1284. Bibcode:2002AGUFM.T62A1284U.
  25. ^ Mahoney, John J.; Clague, David A.; Guillou, Hervé; Zander, Iris van der; Pyle, Douglas; Tardona, Mary; Eason, Deborah E.; Sinton, John M. (1 September 2014). "Ka'ena Volcano—A precursor volcano of the island of O'ahu, Hawai'i". GSA Bulletin. 126 (9–10): 11. Bibcode:2014GSAB..126.1219S. doi:10.1130/B30936.1. ISSN 0016-7606.
  26. ^ Clague et al. 1990, p. 189.
  27. ^ a b Le, Yang & Morgan 2022, p. 2.
  28. ^ Yamamoto, Michiko; Morgan, Jason Phipps (2009). "North Arch volcanic fields near Hawaii are evidence favouring the restite-root hypothesis for the origin of hotspot swells". Terra Nova. 21 (6): 464. Bibcode:2009TeNov..21..452Y. doi:10.1111/j.1365-3121.2009.00902.x. ISSN 1365-3121. S2CID 130652392.
  29. ^ Tackley, Paul J.; Ito, Garrett; Ballmer, Maxim D. (July 2011). "Spatial and temporal variability in Hawaiian hotspot volcanism induced by small-scale convection". Nature Geoscience. 4 (7): 3. Bibcode:2011NatGe...4..457B. doi:10.1038/ngeo1187. ISSN 1752-0908.
  30. ^ Albarède, Francis; Blichert-Toft, Janne; Weis, Dominique; Mattielli, Nadine (1 July 2002). "Hf Isotope Evidence for a Miocene Change in the Kerguelen Mantle Plume Composition". Journal of Petrology. 43 (7): 1337. Bibcode:2002JPet...43.1327M. doi:10.1093/petrology/43.7.1327. ISSN 0022-3530.
  31. ^ a b Clague, Frey & Yang 2003, p. 605.
  32. ^ a b Davis & Clague 2005, p. 298.
  33. ^ Davis & Clague 2005, p. 301.
  34. ^ Poreda et al. 1997, p. 917.
  35. ^ Clague et al. 1990, p. 181.
  36. ^ Sinton et al. 2000, p. 681.
  37. ^ Sinton et al. 2000, p. 682.
  38. ^ Kani, T.; Uto, K. (1 December 2001). "Geochemical Characteristics of Mantle Sources of North Arch Alkalic Volcanism, Hawaii". AGU Fall Meeting Abstracts. 12: V12B–0961. Bibcode:2001AGUFM.V12B0961K.
  39. ^ Davis & Clague 2005, p. 297.
  40. ^ Clague et al. 1990, p. 186.
  41. ^ Holcomb et al. 1989, p. 614.
  42. ^ Clague et al. 1990, p. 188.
  43. ^ Clague et al. 1990, p. 190.
  44. ^ Morishita, Tomoaki; Umino, Susumu; Kimura, Jun-Ichi; Yamashita, Mikiya; Ono, Shigeaki; Michibayashi, Katsuyoshi; Tominaga, Masako; Klein, Frieder; Garcia, Michael O. (2 December 2019). "Workshop report on hard-rock drilling into mid-Cretaceous Pacific oceanic crust on the Hawaiian North Arch". Scientific Drilling. 26: 51. Bibcode:2019SciDr..26...47M. doi:10.5194/sd-26-47-2019.
  45. ^ a b Davis & Clague 2005, p. 306.
  46. ^ Davis & Clague 2005, p. 304.

Sources

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