Taupō Volcanic Zone

Coordinates: 38°40′00″S 176°01′00″E / 38.66667°S 176.01667°E / -38.66667; 176.01667
From Wikipedia, the free encyclopedia
(Redirected from Taupo volcanic zone)

Taupō Volcanic Zone
Volcano and historic lake/caldera locations in the Taupō Volcanic Zone. The distance between the town of Rotorua and the town of Taupō is 80 km. (White Island is not shown.)
Volcano and historic lake/caldera locations in the Taupō Volcanic Zone. The distance between the town of Rotorua and the town of Taupō is 80 km. (White Island is not shown.)
Taupō Volcanic Zone is located in New Zealand
Taupō Volcanic Zone
Taupō Volcanic Zone
Location of Taupō Volcanic Zone in New Zealand
Taupō Volcanic Zone is located in North Island
Taupō Volcanic Zone
Taupō Volcanic Zone
Taupō Volcanic Zone (North Island)
Coordinates: 38°40′00″S 176°01′00″E / 38.66667°S 176.01667°E / -38.66667; 176.01667
LocationNorth Island
AgeMiocene - Holocene
Formed byVolcanic action
Geologysee Taupō Rift
Highest elevation2,797 m (9,177 ft)

The Taupō Volcanic Zone (TVZ) is a volcanic area in the North Island of New Zealand that has been active for at least the past two million years and is still highly active. Mount Ruapehu marks its south-western end and the zone runs north-eastward through the Taupō and Rotorua areas and offshore into the Bay of Plenty. It is part of a larger Central Volcanic Region that extends to the Coromandel Peninsula and has been active for four million years. The zone is contained within the tectonic intra-arc continental Taupō Rift and this rift volcanic zone is widening unevenly east–west with the greatest rate of widening at the Bay of Plenty coast, the least at Mount Ruapehu and a rate of about 8 mm (0.31 in) per year at Taupō. The zone is named after Lake Taupō, the flooded caldera of the largest volcano in the zone, the Taupō Volcano and contains a large central volcanic plateau as well as other landforms.

Activity[edit]

Mount Ngauruhoe

There are numerous volcanic vents and geothermal fields in the zone, with Mount Ruapehu, Mount Ngauruhoe and Whakaari / White Island erupting most frequently. Whakaari has been in continuous activity since 1826 if you count such as steaming fumaroles, but the same applies to say the Okataina volcanic centre.[1] The Taupō Volcanic Zone has produced in the last 350,000 years over 3,900 cubic kilometres (940 cu mi) material, more than anywhere else on Earth, from over 300 silicic eruptions, with 12 of these eruptions being caldera-forming.[2] Detailed stratigraphy in the zone is only available from the Ōkataina Rotoiti eruption but including this event, the zone has been more productive than any other rhyolite predominant volcanic area over the last 50,000 odd years at 12.8 km3 (3.1 cu mi) per thousand years.[3]: 230–232  Comparison of large events in the Taupō volcanic zone over the last 1.6 million years at 3.8 km3 (0.91 cu mi) per thousand years with Yellowstone Caldera's 2.1 million year productivity at 3.0 km3 (0.72 cu mi) per thousand years favours Taupo.[3]: 225  Both the Taupō Volcano and the Ōkataina Caldera have had multiple eruptions in the last 25,000 years. The zone's largest eruption since the arrival of Europeans was that of Mount Tarawera (within the Ōkataina Caldera) in 1886, which killed over 100 people. Early Māori would also have been affected by the much larger Kaharoa eruption from Tarawera around 1315 CE.[4][5]

The last major eruption from Lake Taupō, the Hatepe eruption, occurred in 232 CE.[6] It is believed to have first emptied the lake, then followed that feat with a pyroclastic flow that covered about 20,000 km2 (7,700 sq mi) of land with volcanic ash. A total of 120 km3 (29 cu mi) of material expressed as dense-rock equivalent (DRE) is believed to have been ejected, and over 30 km3 (7.2 cu mi) of material is estimated to have been ejected in just a few minutes. The date of this activity was previously thought to be 186 AD as the ash expulsion was thought to be sufficiently large to turn the sky red over Rome and China (as documented in Hou Han Shu), but this has since been disproven.[6]

Whakaari / White Island

Whakaari / White Island had a major, edifice failure collapse of its volcano dated to 946 BCE ± 52 years. It has been suggested that this was the cause of the tsunami tens of metres tall that went up to 7 kilometres (4.3 mi) inland in the Bay of Plenty at about this time. Although significant tsunami's can be associated with volcanic eruptions, it is unknown if the cause was a relatively small eruption of Whakaari or another cause such as a large local earthquake[7]

Taupō erupted an estimated 1,170 km3 (280 cu mi) of DRE material in its Oruanui eruption 25,580 years ago.[8] This was Earth's most recent eruption reaching VEI-8, the highest level on the Volcanic Explosivity Index.

The Rotorua caldera has been dormant longer, with its main eruption occurring about 225,000 years ago, although lava dome extrusion has occurred within the last 25,000 years.[9][10]

Extent and geological context[edit]

Lady Knox Geyser, Waiotapu geothermal area

The Taupō volcanic zone is approximately 350 kilometres (217 mi) long by 50 kilometres (31 mi) wide. Mount Ruapehu marks its southwestern end, while Whakaari / White Island is considered its northeastern limit.[11]

It forms a southern portion of the active Lau-Havre-Taupō back-arc basin, which lies behind the Kermadec-Tonga Subduction Zone.[12][13] Mayor Island and Mount Taranaki are recently active back arc volcanoes on the New Zealand extension of this arc. Mayor Island / Tūhua is the northern-most shield volcano adjacent to the New Zealand coast, and is believed to have been active in the last 1000 years.[14] It is formed from rhyolite magma.[15] It has a quite complex eruptive history but only with one definite significant Plinian eruption.[14] Mount Taranaki is an andesite cone and the most recent of four Taranaki volcanoes about 140 km (87 mi) west of the Taupō Volcanic Zone.[16]

Associated with the Taupō volcanic zone, intra-arc extension is expressed as normal faulting within a zone known as the Taupō Rift.[17] Volcanic activity continues to the north-northeast, along the line of the Taupō Volcanic Zone, through several undersea volcanoes in the South Kermadec Ridge Seamounts, then shifts eastward to the parallel volcanic arc of the Kermadec Islands and Tonga. Although the back-arc basin continues to propagate to the south-west, with the South Wanganui Basin forming an initial back-arc basin, volcanic activity has not yet begun in this region.[18]

South of Kaikōura the plate boundary changes to a transform boundary with oblique continental collision uplifting the Southern Alps in the South Island. A subduction zone reappears south-west of Fiordland, at the south-western corner of the South Island, although here the subduction is in the opposite direction. Solander Island / Hautere is an extinct volcano associated with this subduction zone, and the only one that protrudes above the sea.

Scientific study[edit]

Tectonics[edit]

In the North Island rifting associated with plate tectonics has defined a Central Volcanic Region, that has been active for four million years and this extends westward from the Taupō volcanic zone through the western Bay of Plenty to the eastern side of the Coromandel Peninsula.[19] The dominant rifting axis associated with the Central Volcanic Region has moved with time, from the back-arc associated Hauraki Rift to the intra-arc Taupō Rift. As there is presently no absolute consensus with regard to the cause of the Taupō Rift's extension or its exceptional current volcanic productivity, some of the discussion on this page has been simplified, rather than all possible models being presented.

Recent scientific work indicates that the Earth's crust below the Taupō Volcanic Zone may be as little as 16 kilometres thick. A film of magma 50 kilometres (30 mi) wide and 160 kilometres (100 mi) long lies 10 kilometres under the surface.[20][21] The geological record indicates that some of the volcanoes in the area erupt infrequently but have large, violent and destructive eruptions when they do. Technically the zone is in the continental intraarc Taupō Rift, which is a continuation of oceanic plate structures associated with oblique Australian and Pacific Plate convergence in the Hikurangi subduction zone. At Taupō the rift volcanic zone is widening east–west at the rate of about 8 mm (0.31 in)/year, while at Mount Ruapehu it is only 2–4 mm (0.079–0.157 in)/year and this increases at the north eastern end at the Bay of Plenty coast to 10–15 mm (0.39–0.59 in)/year.[22] The rift has had three active stages of faulting in the last 2 million years with the modern Taupō rift evolving in the last 25,000 years after the massive Oruanui eruption and now being within two essentially inactive rift systems. These are the surrounding limits of the young Taupō Rift between 25,000 and 350,000 years and old Taupō Rift system whose northern boundary is now located well to the north of the other two being created before 350,000 years ago.[22]

The Tauranga Volcanic Centre which was active between 2.95 to 1.9 million years ago, and was previously classified as part of the Central Volcanic Region,[19] appears now to be in a tectonic continuum with the Taupō Volcanic Zone. Recent ocean floor tephra studies off the east coast of the North Island have shown an abrupt compositional change in these, from about 4.5 million years ago, that has been suggested to distinguish Coromandel Volcanic Zone activity from that of the Taupō Volcanic Zone.[23] Further the distinctive Waiteariki ignimbrite that erupted 2.1 million years ago in a supereruption, presumably from the gravity anomaly defined Omanawa Caldera,[24] is within the postulated borders of the old Taupō Rift.[25]

Faults[edit]

The multiple intra-rift faults are some of the most active in the country and some have the potential to create over magnitude 7 events. The fault structures are perhaps most well characterised related to the Ruapehu and Tongariro grabens. The recent deposits from major eruptions and lake features mean many potentially significant faults are uncharacterised, either completely (for example the 6.5 MW 1987 Edgecumbe earthquake resulted in the mapping of the Edgecumbe fault for the first time) or frequency of events and their likely magnitude are not understood. It can not be assumed that just because the rate of expansion of the rift is greatest near the coast that this is where most significant tectonic earthquakes in terms of human risk will be. The Waihi Fault Zone south of Lake Taupō and associated with the Tongariro graben has a particular risk of inducing massive landslips which has caused significant loss of life and appears to be more active than many other faults in the zone.

Volcanism[edit]

In 1886, Mount Tarawera produced New Zealand's largest historic eruption since European colonisation

The north (Whakatane Graben – Bay of Plenty) part of the zone is predominantly formed from andesitic magma[26][27] and represented by the continuously active Whakaari / White Island andesitedacite stratovolcano. Although Strombolian activity has occurred the explosive eruptions are typically phreatic or phreatomagmatic.[28] The active emergent summit tops the larger, 16 kilometres (9.9 mi) × 18 kilometres (11 mi), submarine volcano with a total volume of 78 km3 (19 cu mi).[29][30][31][32]

The central part of the zone is composed of eight caldera centres the oldest of which is the Mangakino caldera which was active more than a million years ago (1.62–0.91 Ma).[26] This produced ignimbrite that 170 km (110 mi) away in Auckland is up to 9 m (30 ft) thick.[33] Other than the now buried Kapenga caldera there are five caldera centres, Rotorua, Ohakuri, Reporoa, Ōkataina and Taupō. These have resulted from massive infrequent eruptions of gaseous very viscous rhyolite magma which is rich in silicon, potassium, and sodium and created the ignimbrite sheets of the North Island Volcanic Plateau. The detailed composition suggests subduction erosion might play a predominant role in producing this rhyolite,[34]: abstract  as later assimilation and fractional crystallization of primary basalt magma, is difficult to model to explain the composition and volumes erupted.[35] This central zone has had the largest number of very large silicic caldera-forming eruptions recently on earth as mentioned earlier.[36][3]

During a period of less than 100,000 years commencing with the massive Whakamaru eruption about 335,000 years ago of greater than 2,000 km3 (480 cu mi) dense-rock equivalent of material, just to the north of the present Lake Taupō, over 4,000 km3 (960 cu mi) total was erupted. These eruptions essentially defined the limits of the present central volcanic plateau, although its current central landscape is mainly a product of later smaller events over the last 200,000 years than the Whakamaru eruption. The other volcanic plateau defining eruptions were to the west, the 150 km3 (36 cu mi) Matahina eruption of about 280,000 years ago, the mainly tephra 50 km3 (12 cu mi) Chimp (Chimpanzee) eruption between 320 and 275 ka, the central 50 km3 (12 cu mi) Pokai eruption of about 275 ka, and the paired Mamaku to the north and east central Ohakuri eruptions of about 240,000 years ago that together produced more than 245 km3 (59 cu mi) dense-rock equivalent of material.[36] The southern Taupō Volcano Oruanui eruption about 25,600 years ago produced 530 km3 (130 cu mi) dense-rock equivalent of material and its recent Hatepe eruption of 232 CE ± 10 years had 120 km3 (29 cu mi) dense-rock equivalent.[6] Since the Whakamaru eruption the central part of the zone has dominated, so that when the whole zone is considered there has been about 3,000 km3 (720 cu mi) of rhyolite, 300 km3 (72 cu mi) of andesite, 20 km3 (4.8 cu mi) of dacite and 5 km3 (1.2 cu mi) of basalt erupted.[3]: 228, 231 

Less gaseous rhyolite magma dome building effusive eruptions have built features such as the Horomatangi Reefs or Motutaiko Island in Lake Taupō or the lava dome of Mount Tarawera. This later as part of the Ōkataina caldera complex is the highest risk volcanic field in New Zealand to man.[37] Mount Tauhara adjacent to Lake Taupō is actually a dacitic dome [38] and so intermediate in composition between andesite and rhyolite but still more viscous than basalt which is rarely found in the zone.[39]

The southern part of the zone contain classic volcanic cone structure formed from andesite magma in effusive eruptions that cool to form dark grey lava if gas-poor or scoria if gas-rich of this part of the zone. Mount Ruapehu, the tallest mountain in the North Island, is a 150 km3 (36 cu mi) andesite cone surrounded by a 150 km3 (36 cu mi) ring-plain.[40] This ring plain is formed from numerous volcanic deposits created by slope failure, eruptions, or lahars. Northwest of Ruapehu is Hauhungatahi, the oldest recorded volcano in the south of the plateau,[40] with to the north the two prominent volcanic mountains in the Tongariro volcanic centre being Tongariro and Ngauruhoe which are part of a single composite stratovolcano.

Risks[edit]

Southwest side of Mount Tarawera, Mount Edgecumbe on the background.

The most likely risk is earthquake associated with multiple active faults,[41] such as within the Taupō Fault Belt, but many faults will be uncharacterised as was the case with the 1987 Edgecumbe earthquake.[42] Earthquakes can be associated with landslides and inland or coastal tsunami that can result in great loss of life and both have happened on the Waihi Fault Zone.[43] The relative low grade volcanic activity of the andesite volcanoes at each end of the zone has resulted in recorded history in both direct loss of life and disrupted transport and tourism. The only high grade eruption in recorded history was atypically basaltic from Mount Tarawera and although very destructive is not likely to be a perfect model for the more typical and often larger rhyolitic events associated with the Taupō Volcano and the Ōkataina Caldera.[44] As mentioned earlier the Ōkataina caldera complex is the highest risk volcanic field risk in New Zealand to man[37] and the recent frequency of rhyolitic events there is not reassuring, along with the timescale of likely warning of such an event.[44] These eruptions are associated with tephra production that results in deep ash fall over wide areas (e.g. the Whakatane eruption of ~ 5500 years ago had 5 mm (0.20 in) ashfall 900 km (560 mi) away on the Chatham Islands) `[45] pyroclastic flows and surges, which rarely have covered large areas of the North Island in ignimbrite sheets, earthquakes, lake tsunamis, prolonged lava dome growth and associated block and ash flows with post-eruption lahars and flooding.[44]

Mount Ruapehu1886 eruption of Mount TaraweraMount TaraweraTaupō VolcanoHatepe eruptionTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoŌkataina CalderaTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoŌkataina CalderaŌkataina CalderaTaupō VolcanoTaupō VolcanoTaupō VolcanoTaupō VolcanoMount TaraweraŌkataina CalderaMount TaraweraMount TaraweraŌkareka EmbaymentOruanui eruptionTaupō Volcano

Volcanoes, lakes and geothermal fields[edit]

Map
Map of selected volcanic features as rectangular symbols for the Taupō Volcanic Zone. Volcanoes classified as active are shown as red, other notable volcanoes (there are many more) are shown as orange, geothermal areas as light blue and if active hydrothermal eruptions as blue. It is possible by clicking on the map to get a full screen view that enables mouseover to show a label (often wiki-linked) for each symbol.
Map
Map of selected surface volcanic deposits centered on the Taupō Volcanic Zone, allowing wider volcanic context. Clicking on the map enlarges it, and enables panning and mouseover of volcanic deposits name/wikilink and ages before present. The key to the shading of the volcanics that are shown is rhyolite - violet, ignimbrite - lighter shades of violet, dacite - purple, basalt - brown, monogenetic basalts - dark brown, undifferentiated basalts of the Tangihua Complex in Northland Allochthon - light brown, arc basalts - deep orange brown, arc ring basalts -orange brown, andesite - red, basaltic andesite`- light red, and plutonic - gray. White shading has been used for postulated calderas (usually subsurface now).

The following Volcanic Centres belong to the modern Taupō Volcanic Zone in what proved to be an evolving classification scheme:

Satellite view of the Lake Rotorua Caldera. Mount Tarawera is in the lower right corner.
Recent major volcanic features Lake Taupō showing relationship to recent volcanic vents in red and present active geothermal systems in light blue.
Composite satellite image of Mount Ruapehu

Rotorua, Ōkataina, Maroa, Taupō, Tongariro and Mangakino.[46][47] The old zone almost certainly contains volcanoes in the Tauranga Volcanic Centre.[48]

Other important features of the TVZ include the Ngakuru and Ruapehu grabens.

Note[edit]

Craters of the Moon geothermal area

There is more recent, somewhat different classification, by some of the same authors, that uses the term caldera complex:[26]

Panorama across Lake Taupō

See also[edit]

References[edit]

  1. ^ Waight, Tod E.; Troll, Valentin R.; Gamble, John A.; Price, Richard C.; Chadwick, Jane P. (2017-07-01). "Hf isotope evidence for variable slab input and crustal addition in basalts and andesites of the Taupo Volcanic Zone, New Zealand". Lithos. 284–285: 222–236. Bibcode:2017Litho.284..222W. doi:10.1016/j.lithos.2017.04.009. ISSN 0024-4937.
  2. ^ Kósik, Szabolcs; Nemeth, Karoly; Danisik, Martin; Procter, Jonathan; Schmitt, Axel; Friedrichs, Bjarne; Stewart, Robert (2021-01-19). "Shallow subaqueous to emergent intra-caldera silicic volcanism of the Motuoapa Peninsula, Taupo Volcanic Zone, New Zealand – New constraints from geologic mapping, sedimentology and zircon geochronology". Journal of Volcanology and Geothermal Research. 411: 107180. doi:10.1016/j.jvolgeores.2021.107180. S2CID 233771486.
  3. ^ a b c d Wilson, C.J.N.; Gravley, D.M.; Leonard, G.S.; Rowland, J.V. (2009). "Volcanism in the central Taupo Volcanic Zone, New Zealand: tempo, styles and controls". In Thordarson, T.; Larsen, G.; Self, S.; Rowland, S.; Hoskuldsson, Á. (eds.). Studies in volcanology: the legacy of George Walker. IAVCEI Spec Pub 2. pp. 225–247. doi:10.1144/IAVCEl002.12. ISBN 978-1-86239-280-9.
  4. ^ Bonadonna, C.; Connor, C. B.; Houghton, B. F.; Connor, L.; Byrne, M.; Laing, A.; Hincks, T.K. (2005-03-15). "Probabilistic modeling of tephra dispersal: Hazard assessment of a multiphase rhyolitic eruption at Tarawera, New Zealand". Journal of Geophysical Research: Solid Earth. 110 (B3). Bibcode:2005JGRB..110.3203B. doi:10.1029/2003JB002896.
  5. ^ David, Lowe (2006). "Polynesian settlement and impacts of volcanism on early Maori society" (PDF). In Lowe, D.J. (ed.). Guidebook for 'Land and Lakes' field trip, New Zealand Society of Soil Science Biennial Conference, Rotorua, held in 27–30 November 2006. Lincoln: New Zealand Society of Soil Science. pp. 50–55.
  6. ^ a b c Illsley-Kemp, Finnigan; Barker, Simon J.; Wilson, Colin J. N.; Chamberlain, Calum J.; Hreinsdóttir, Sigrún; Ellis, Susan; Hamling, Ian J.; Savage, Martha K.; Mestel, Eleanor R. H.; Wadsworth, Fabian B. (2021-06-01). "Volcanic Unrest at Taupō Volcano in 2019: Causes, Mechanisms and Implications". Geochemistry, Geophysics, Geosystems. 22 (6): 1–27. Bibcode:2021GGG....2209803I. doi:10.1029/2021GC009803.
  7. ^ de Lange, Willem; Moon, Vicki (2016). Volcanic generation of tsunamis: Two New Zealand palaeo-events in Submarine Mass Movements and their Consequences (PDF). 56.
  8. ^ Dunbar, Nelia W.; Iverson, Nels A.; Van Eaton, Alexa R.; Sigl, Michael; Alloway, Brent V.; Kurbatov, Andrei V.; Mastin, Larry G.; McConnell, Joseph R.; Wilson, Colin J. N. (2017-09-25). "New Zealand supereruption provides time marker for the Last Glacial Maximum in Antarctica". Scientific Reports. 7 (1): 12238. Bibcode:2017NatSR...712238D. doi:10.1038/s41598-017-11758-0. PMC 5613013. PMID 28947829.
  9. ^ Milner, David M (2001). The structure and eruptive history of Rotorua Caldera, Taupo Volcanic Zone, New Zealand (Thesis).
  10. ^ "Rotorua". Global Volcanism Program. Smithsonian Institution. Retrieved 2010-08-31.
  11. ^ Gamble, J. A.; Wright, I. C.; Baker, J. A. (1993). "Seafloor geology and petrology in the oceanic to continental transition zone of the Kermadec-Havre-Taupo Volcanic Zone arc system, New Zealand". New Zealand Journal of Geology and Geophysics. 36 (4): 417–435. doi:10.1080/00288306.1993.9514588. Archived from the original on 2008-11-22.
  12. ^ Caratori Tontini, F.; Bassett, D.; de Ronde, C. E. J.; Timm, C.; Wysoczanski, R. (2019). "Early evolution of a young back-arc basin in the Havre Trough" (PDF). Nature Geoscience. 12 (10): 856–862. Bibcode:2019NatGe..12..856C. doi:10.1038/s41561-019-0439-y. S2CID 202580942.
  13. ^ Parson, L. M.; Wright, I. C. (1996). "The Lau-Havre-Taupo back-arc basin: A southward-propagating, multi-stage evolution from rifting to spreading". Tectonophysics. 263 (1–4): 1–22. Bibcode:1996Tectp.263....1P. doi:10.1016/S0040-1951(96)00029-7.
  14. ^ a b Houghton, B.F.; Wilson, J. N. C; Weaver, S.D.; Lanphere, M.A.; Barclay, J (1995). "Mayor Island Geology". Volcanic Hazards at Mayor Island. [Palmerston North, NZ]: Ministry of Civil Defence. Volcanic Hazards Information Series 6.: 1–23.
  15. ^ Houghton, Bruce F.; Weaver, S.D.; Wilson, J. N.; Lanphere, M.A. (1992). "Evolution of a quaternary peralkaline volcano: Mayor Island, New Zealand". Journal of Volcanology and Geothermal Research. 51 (3): 217–236. Bibcode:1992JVGR...51..217H. doi:10.1016/0377-0273(92)90124-V.
  16. ^ Price, R. C.; Stewart, R. B.; Woodhead, J. D.; Smith, I. E. M. (1999). "Petrogenesis of High-K Arc Magmas: Evidence from Egmont Volcano, North Island, New Zealand". Journal of Petrology. 40 (1): 167–197. doi:10.1093/petroj/40.1.167.
  17. ^ Holden, Lucas; Wallace, L.; Beavan, J.; Fournier, Nico; Cas, Raymond; Ailleres, Laurent; Silcock, David. (2015-07-28). "Contemporary ground deformation in the Taupo Rift and Okataina Volcanic Centre from 1998 to 2011, measured using GPS". Geophysical Journal International. 202 (3): 2082–2105. doi:10.1093/gji/ggv243.
  18. ^ Villamor, P.; Berryman, K. R. (2006). "Evolution of the southern termination of the Taupo Rift, New Zealand". New Zealand Journal of Geology and Geophysics. 49: 23–37. doi:10.1080/00288306.2006.9515145.
  19. ^ a b Cole, J.W.; Darby, D.J.; Stern, T.A. (1995). "Taupo Volcanic Zone and Central Volcanic Region: Backarc Structures of North Island, New Zealand". In Taylor, Brian (ed.). Backarc Basins: Tectonics and Magmatism. New York: Plenum. p. 3. ISBN 978-1-4615-1843-3.
  20. ^ Easton, Paul (15 September 2007). "Central North Island sitting on magma film". The Dominion Post. Retrieved 16 March 2008.
  21. ^ Heise, W.; Bibby, H.M.; Caldwell, T.G. (2007). "Imaging magmatic Processes in the Taupo Volcanic Zone (New Zealand) with Magnetotellurics" (PDF). Geophysical Research Abstracts. 9. 01311.
  22. ^ a b Villimor, P.; Berryman, K. R.; Ellis, S. M.; Schreurs, G.; Wallace, L. M.; Leonard, G. S.; Langridge, R. M.; Ries, W. F. (2017-10-04). "Rapid Evolution of Subduction-Related Continental Intraarc Rifts: The Taupo Rift, New Zealand". Tectonics. 36 (10): 2250–2272. Bibcode:2017Tecto..36.2250V. doi:10.1002/2017TC004715. S2CID 56356050.
  23. ^ Pank, K; Kutterolf, S; Hopkins, JL; Wang, KL; Lee, HY; Schmitt, AK (2023). "Advances in New Zealand's tephrochronostratigraphy using marine drill sites: The Neogene". Geochemistry, Geophysics, Geosystems. 24 (8). e2023GC010866. doi:10.1029/2023GC010866.
  24. ^ Stagpoole, V; Miller, C; Caratori, Tontini F; Brakenrig, T; Macdonald, N (2021). "A two million-year history of rifting and caldera volcanism imprinted in new gravity anomaly compilation of the Taupō Volcanic Zone, New Zealand". New Zealand Journal of Geology and Geophysics. 64 (2–3): 358–371. doi:10.1080/00288306.2020.1848882. S2CID 230527523.
  25. ^ Prentice, Marlena; Pittari, Adrian; Lowe, David J.; Kilgour, Geoff; Kamp, Peter J.J.; Namaliu, Miriam (2022). "Linking proximal ignimbrites and coeval distal tephra deposits to establish a record of voluminous Early Quaternary (2.4–1.9 Ma) volcanism of the Tauranga Volcanic Centre, New Zealand". Journal of Volcanology and Geothermal Research. 429 (107595): 107595. doi:10.1016/j.jvolgeores.2022.107595. ISSN 0377-0273. S2CID 249264293.
  26. ^ a b c d Cole, J. W.; Spinks, K. D. (2009). "Caldera volcanism and rift structure in the Taupo Volcanic Zone, New Zealand". Special Publications. 327 (1). London: Geological Society: 9–29. Bibcode:2009GSLSP.327....9C. doi:10.1144/SP327.2. S2CID 131562598.
  27. ^ Hiess, J; Cole, JW; Spinks, KD (2007). High-Alumina Basalts of the Taupo Volcanic Zone, New Zealand: Influence of the Crust and Crustal Structure (PDF). p. 36 – via Part of a BSc Project by Hiess, J. (University of Canterbury).
  28. ^ Houghton, B. F.; Nairn, I. A. (1 December 1991). "The 1976–1982 Strombolian and phreatomagmatic eruptions of White Island, New Zealand: eruptive and depositional mechanisms at a 'wet' volcano". Bulletin of Volcanology. 54 (1): 25–49. Bibcode:1991BVol...54...25H. doi:10.1007/BF00278204. S2CID 128897275.
  29. ^ Cole, J.W., Thordarson, T. and Burt, R.M., 2000. Magma origin and evolution of White Island (Whakaari) volcano, Bay of plenty, New Zealand. Journal of Petrology, 41(6), pp.867–895.
  30. ^ Moon, V., Bradshaw, J. and de Lange, W., 2009. Geomorphic development of White Island Volcano based on slope stability modelling. Engineering Geology, 104(1–2), pp.16–30.
  31. ^ Jimenez, C., 2015. Magmatic-hydrothermal system at White Island volcano, North Island, New Zealand. in M. Calder, ed., pp. 35–46, JCU SEG Student Chapter New Zealand, North Island Field Trip 2015 Guide Book. Queensland, Australia: James Cook University SEG Student Chapter, Society of Economic Geologists, Inc.
  32. ^ Duncan, A.R. (1970). The petrology and petrochemistry of andesite volcanoes in Eastern Bay of Plenty, New Zealand (PDF) (Thesis). Victoria University of Wellington, New Zealand. 362.
  33. ^ "GUIDEBOOK FOR LAND AND LAKES FIELD TRIP". New Zealand Society of Soil Science. 2006-11-28.
  34. ^ Santa Cruz, Carlos Rodolfo Corella (2023). Subduction cycling and its controls on hyperactive volcanism in the Taupo Volcanic Zone, New Zealand: a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Earth Science (Thesis). Massey University, Palmerston North, New Zealand.
  35. ^ Santa Cruz, CRC; Zellmer, GF; Stirling, CH; Straub, SM; Brenna, M; Reid, MR; Németh, K; Barr, D (1 July 2023). "Transcrustal and source processes affecting the chemical characteristics of magmas in a hyperactive volcanic zone". Geochimica et Cosmochimica Acta. 352: 86–106. doi:10.1016/j.gca.2023.05.003.
  36. ^ a b Gualda, Guilherme A. R.; Gravley, Darren M.; Connor, Michelle; Hollmann, Brooke; Pamukcu, Ayla S.; Bégué, Florence; Ghiorso, Mark S.; Deering, Chad D. (2018). "Climbing the crustal ladder: Magma storage-depth evolution during a volcanic flare-up". Science Advances. 4 (10): eaap7567. doi:10.1126/sciadv.aap7567. PMC 6179376. PMID 30324132.
  37. ^ a b Doherty, Angela Louise (2009). "Blue‐sky eruptions, do they exist? Implications for monitoring New Zealand's volcanoes" (PDF). University of Canterbury. Retrieved 2022-06-07.
  38. ^ Volcanic Hazards Working Group of the Civil Defence Scientific Advisory Committee, which includes scientists from the Institute of Geological and Nuclear Sciences and the Universities, Number seven "Taupo Volcanic Centre" Archived 2006-10-06 at the Wayback Machine
  39. ^ Bertrand, E.A.; Kannberg, P.; Caldwell, T.G.; Heise, W.; Constable, S.; Scott, B.; Bannister, S.; Kilgour, G.; Bennie, S.L.; Hart, R.; Palmer, N. (2022). "Inferring the magmatic roots of volcano-geothermal systems in the Rotorua Caldera and Okataina Volcanic Centre from magnetotelluric models". Journal of Volcanology and Geothermal Research. 431 (107645): 107645. doi:10.1016/j.jvolgeores.2022.107645. ISSN 0377-0273. S2CID 251526385.
  40. ^ a b Leonard, Graham S.; Cole, Rosie P.; Christenson, Bruce W.; Conway, Chris E.; Cronin, Shane J.; Gamble, John A.; Hurst, Tony; Kennedy, Ben M.; Miller, Craig A.; Procter, Jonathan N.; Pure, Leo R.; Townsend, JDougal B.; White, James D. L.; Wilson, Colin J. N. (2021-05-02). "Ruapehu and Tongariro stratovolcanoes: a review of current understanding". New Zealand Journal of Geology and Geophysics. 64 (2–3): 389–420. doi:10.1080/00288306.2021.1909080. hdl:10468/11258. S2CID 235502116.
  41. ^ "Villamor, P.; Ries, W.; Zajac, A. Rotorua District Council Hazard Studies: Active fault hazards. GNS Science Consultancy Report" (PDF). 2010.
  42. ^ Franks, C.A.M.; Beetham, R.D.; Salt, G.A. (1989). "Ground damage and seismic response resulting from the 1987 Edgecumbe earthquake, New Zealand". New Zealand Journal of Geology and Geophysics. 32 (1): 135–44. doi:10.1080/00288306.1989.10421397.
  43. ^ Gómez‐Vasconcelos, Martha; Villamor, Pilar; Procter, Jon; Palmer, Alan; Cronin, Shane; Wallace, Clel; Townsend, Dougal; Leonard, Graham (2018). "Characterisation of faults as earthquake sources from geomorphic data in the Tongariro Volcanic Complex, New Zealand". New Zealand Journal of Geology and Geophysics. 62: 131–142. doi:10.1080/00288306.2018.1548495. S2CID 134094861.
  44. ^ a b c Darragh, Miles Benson (2004). Eruption Processes of the Okareka and Rerewhakaaitu eruption episodes; Tarawera Volcano, New Zealand (PDF) (Thesis).
  45. ^ Holt, Katherine A.; Lowe, David J.; Hogg, Alan G.; Wallace, R. Clel (2011). "Distal occurrence of mid-Holocene Whakatane Tephra on the Chatham Islands, New Zealand, and potential for cryptotephra studies". Quaternary International. 246 (1–2): 344–351. doi:10.1016/j.quaint.2011.06.026. hdl:10289/5454. ISSN 1040-6182.
  46. ^ Cole, J.W. (1990). "Structural control and origin of volcanism in the Taupo volcanic zone, New Zealand". Bulletin of Volcanology. 52 (6): 445–459. Bibcode:1990BVol...52..445C. doi:10.1007/BF00268925. S2CID 129091056.
  47. ^ "New Zealand".
  48. ^ Pittari, Adrian; Prentice, Marlena L.; McLeod, Oliver E.; Zadeh, Elham Yousef; Kamp, Peter J. J.; Danišík, Martin; Vincent, Kirsty A. (2021). "Inception of the modern North Island (New Zealand) volcanic setting: spatio-temporal patterns of volcanism between 3.0 and 0.9 Ma" (PDF). New Zealand Journal of Geology and Geophysics. 64 (2–3): 250–272. doi:10.1080/00288306.2021.1915343. S2CID 235736318.
  49. ^ a b c d e f g "Large Holocene Eruptions". Global Volcanism Program. Archived from the original on 2012-04-15.
  50. ^ Newhall, Christopher G.; Dzurisin, Daniel (1988). "Historical unrest at large calderas of the world". USGS Bulletin. 1855: 1108. Citing Scott, B.J. (1986). Gregory, J.G.; Watters, W.A. (eds.). "Volcanic hazards assessment in New Zealand: Monitoring at Okataina Volcanic Centre". New Zealand Geol. Surv. Rec. 10: 49–54.
  51. ^ Okataina Volcanic Center, New Zealand
  52. ^ Nairn, I.A. (2002). Geology of the Okatania Volcanic Centre. Geological Map 25. Institute of Geological and Nuclear Sciences. p. 156.
  53. ^ a b Hodgson, K. A.; Nairn, I. A. (August 2004). "The Sedimentation and Drainage History of Haroharo Caldera and The Tarawera River System, Taupo Volcanic Zone, New Zealand" (PDF). Operations Publication 2004/03. Environment Bay of Plenty: 7. ISSN 1176-5550. Archived from the original (PDF) on 2010-05-22.
  54. ^ Kósik, S.; Németh, K.; Lexa, J.; Procter, J.N. (2019). "Understanding the evolution of a small-volume silicic fissure eruption: Puketerata Volcanic Complex, Taupo Volcanic Zone, New Zealand". Journal of Volcanology and Geothermal Research. 383: 28–46. doi:10.1016/j.jvolgeores.2017.12.008. ISSN 0377-0273. S2CID 134914216.
  55. ^ Krippner, Stephen J. P.; Briggs, Roger M.; Wilson, Colin J. N.; Cole, James W. (1998). "Petrography and geochemistry of lithic fragments in ignimbrites from the Mangakino Volcanic Centre: implications for the composition of the subvolcanic crust in western Taupo Volcanic Zone, New Zealand". New Zealand Journal of Geology and Geophysics. 41 (2): 187–199. doi:10.1080/00288306.1998.9514803.

External links[edit]