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Alpine Fault

May 02, 2024

The Alpine Fault is a geological fault that runs almost the entire length of New Zealand's South Island, being about 600 km (370 mi).[n 1] long, and forms the boundary between the Pacific Plate and the Australian Plate.[4] The Southern Alps have been uplifted on the fault over the last 12 million years in a series of earthquakes. However, most of the motion on the fault is strike-slip (side to side), with the Tasman district and West Coast moving north and Canterbury and Otago moving south. The average slip rates in the fault's central region are about 38 mm (1.5 in) a year, very fast by global standards.[5] The last major earthquake on the Alpine Fault was in about 1717 AD with a great earthquake magnitude of Mw8.1± 0.1.[2] The probability of another one occurring before 2068 was estimated at 75 percent in 2021.[6][7]

Alpine Fault
Movement along the Alpine Fault is deforming the continent of Zealandia, with the southern part (on the Pacific Plate) sliding past and slightly onto the northwest part (on the Australian Plate).
Map of active Alpine Fault on land (red). Click on the map to enable mouse over of fault features.[1]
EtymologySouthern Alps
CountryNew Zealand
RegionWest Coast and Southland Regions
Characteristics
RangeSouthern Alps
Length600 km (370 mi)
StrikeNE-SW
Displacement30 mm (1.2 in)/yr
Tectonics
PlateAustralian, Pacific
StatusActive
Earthquakes1717 prehistoric
TypeStrike-slip fault
MovementUp to Mw8.2,[2] dextral/convergent, east side up
AgeMiocene-Holocene 12–0.0003 Ma[3]
OrogenyKaikoura
New Zealand geology database (includes faults)
Snow delineates the escarpment formed by the Alpine Fault along the Southern Alps' north-west edge, near the South Island's west coast. This satellite image shows the aftermath of a blizzard that hit the island in July 2003.

Geographic extent and plate motion edit

 
Map of the northern end of the Alpine Fault and Marlborough Fault System.

The Pacific Plate and Indo-Australian Plate boundary forms the Macquarie Fault Zone in the Puysegur Trench off the southwestern corner of the South Island and comes onshore as the Alpine Fault just north of Milford Sound. The Alpine Fault then runs the length of the South Island just west of the Southern Alps to near Lewis Pass in the central northern section of the island. At this point, it splits into a set of smaller faults known as the Marlborough Fault System. This set of faults, which includes the Wairau Fault, the Hope Fault, the Awatere Fault, and the Clarence Fault, transfer displacement between the Alpine Fault and the Hikurangi subduction zone to the north. The Hope Fault is thought to represent the primary continuation of the Alpine Fault.[8]

Tectonics edit

The Australian Plate, which is in the process of again separating from the Indo-Australian Plate,[9] is subducting towards the east south of the South Island and the Pacific Plate is subducting towards the west to the north. In the middle, the Alpine Fault is a transform boundary and has both dextral (right-lateral) strike-slip movement and uplift on the southeastern side.[2] The uplift is due to an element of convergence between the plates, meaning that the fault has a significant high-angle reverse oblique component to its displacement.[4][10]

In the northern section of the fault the transition to the Marlborough Fault System reflects transfer displacement between the mainly transform plate boundary of the Alpine fault and the mainly destructive boundary further northwards from the Hikurangi Subduction Zone to the Kermadec Trench.

The Alpine Fault has the greatest uplift of the Pacific Plate near Aoraki / Mount Cook in its central section. Here the relative motion between the two plates averages 37–40 mm a year. This is distributed as 36–39 mm of horizontal and 6–10 mm upwards movement on the fault's plane per year.[5]

At the southern end of the fault there is effectively no uplift component of the Pacific Plate[11] and other faults in Fiordland, the Otago fault system and in Canterbury such as the Ostler Fault Zone and those associated with the 7.1 MW Darfield earthquake share the strain as a result of the plate collision.[12] The uplift in this South Westland region of the fault which has a dextral strike-slip rate of about 28 mm (1.1 in)/year is on the Australian plate side of it and has meter scale vertical uplift every 290 years odd.[3]

Geological origin and evolution edit

 
New Zealand before the activation of the Alpine Fault (30 Ma).
 
Outcrop showing hydrothermally altered cataclasite in green, within the Alpine Fault zone, Waikukupa River.
 
Alpine Fault outcrop showing banded cataclasite and breccia, Waikukupa River.

Between 25 and 12 million years ago the movement on the proto-Alpine Fault was exclusively strike-slip. The Southern Alps had not yet formed and most of New Zealand was covered in water.[10] Then uplift slowly began as the plate motion became slightly oblique to the strike of the Alpine Fault. In the last 12 million years, the Southern Alps have been uplifted approximately 20 km (12 mi), however, as this has occurred more rain has been trapped by the mountains leading to more erosion.[4] This, along with isostatic constraints, has kept the Southern Alps less than 4,000 m (13,000 ft) high.

Uplift on the Alpine Fault has led to the exposure of deep metamorphic rocks near the fault within the Southern Alps. This includes mylonites and the Alpine Schist, which increases in metamorphic grade towards the fault. The eroded material has formed the Canterbury Plains.[10] The Alpine Fault is not a single structure but often splits into pure strike-slip and dip-slip components.[11][13] Near the surface, the fault can have multiple rupture zones.[5]

Fault zone geology edit

The fault zone is exposed at numerous locations along the West Coast,[14] and typically consists of a 10 to 50 m wide fault gouge zone[2] with pervasive hydrothermal alteration. This last is because water penetrates down to up to 6 km (3.7 mi) through hot rock associated with the fault. The water then can arise in hot springs with temperatures of over 50 °C (122 °F) in the fault valley,[15] although the temperature of the water at depth is much more extreme.[16] Most of the movement along the fault occurs in this zone.[5] In outcrop, the fault zone is overlain by mylonites which formed at depth and have been uplifted by the fault.[17]

A structural study[18] of a segment of the Alpine Fault to the southwest of Fiordland examined the Dagg Basin, an offshore sedimentary basin at 3,000 m (9,800 ft) depth. Basin sediments are primarily from Pleistocene glaciation, and structures within them reveal a past complexity that is no longer present in the basin. The current structure is a pull-apart basin along a releasing bend in the Alpine Fault, with a segment of inverted basin along the southern edge due to transpression. The study discussed the short-lived nature of the releasing bend (on the order of 105 to 106 years), during which there were 450 – 1650 m of dextral displacement. The nature of the displacement served as an example of the kinds of ephemeral structures that can develop along a mature strike-slip fault system.[18]

Earthquakes edit

There have been no major historical earthquakes on the Alpine Fault. Because of this, during the mid-20th century it was speculated that the Alpine Fault creeps without making large earthquakes.[19] However, it is now inferred by multiples lines of evidence that the Alpine Fault ruptures, creating major earthquakes approximately every few hundred years. The last whole fault rupture event was in 1717 and is now known to have been a great earthquake of Mw 8.1± 0.1.[2] There is also fair evidence for a post 1717 event confined to North Westland section of the fault but the date is unclear.[2] There are two modes of large earthquake behaviour with either major (MW 7–8) or great (MW > 8) earthquakes and predicting the next mode is a challenge as these appear to evolve over multiple seismic cycles in response to along-strike differences in geometry.[20]

Prehistoric edit

The Māori arrived in New Zealand c.1300 but never reached a high population density in the colder South Island.[21] Therefore, while earthquakes are an important part of Māori oral tradition, no stories have been passed down about South Island earthquakes. Over the last thousand years, the major ruptures along the Alpine Fault, causing earthquakes of about magnitude 8 had previously been determined to have occurred at least four times.[22] These had separation of between 100 and 350 years.[22] The 1717 quake appeared to have involved a rupture along nearly 400 kilometres (250 mi) of the southern two-thirds of the fault. Scientists say that a similar earthquake could happen at any time, as the interval since 1717 is longer than the intervals between the earlier events.[23] Newer research carried out by the University of Otago, the Australian Nuclear Science and Technology Organisation and others has revised the dates and nature of the earthquakes and given greater understanding of their number. Studies at Haast towards the centre of the fault only identified three major rupture events in the last 1000 years.[24] Studies at the far southern end identified seven events in the last 2000 years and the most southern 20 km (12 mi) of the fault has had 27 events since 6000 BCE.[3] This information has been updated with better dating techniques and is summarised in the following timeline for the various sections of the fault.[2]

This work suggests that large fault ruptures occurred in 1717, about 1400, about 1100 and about 390 CE.[2]

Historic edit

There have been no major earthquakes on the Alpine Fault in historic times; its southern and northern offshoots have, however, experienced sizable earthquakes:

Prediction of next earthquake edit

In 2012, GNS Science researchers published an 8000-year timeline of 24 major earthquakes on the (southern end of the) fault from sediments at Hokuri Creek, near Lake McKerrow in north Fiordland. In earthquake terms, the up to 800 kilometres (500 mi)[n 1] long[24] fault was remarkably consistent, rupturing on average every 330 years, at intervals ranging from 140 years to 510 years.[25] In 2017, GNS researchers revised the figures after they combined updated Hokuri site records with a thousand-year record from another site, 20 km away at John O'Groats River, to produce a record of 27 major earthquake events during the 8000-year period.[3] This gave a mean recurrence rate of 291 years, plus or minus 23 years,[3] versus the previously estimated rate of 329 years, plus or minus 26 years. In the new study, the interval between earthquakes ranged from 160 to 350 years, and the probability of an earthquake occurring in the 50 years following 2017 was estimated at 29 percent for this southern sector of the fault alone.[26][2]

Projected effects of a rupture edit

Large ruptures can also trigger earthquakes on the faults continuing north from the Alpine Fault. There is paleotsunami evidence of near-simultaneous ruptures of the Alpine Fault and Wellington (and/or other major) faults to the north having occurred at least twice in the past 1,000 years.[27] A 2018 study says that a significant rupture in the Alpine Fault could lead to roads (particularly in or to the West Coast) being blocked for months, as with the 2016 Kaikōura earthquake, with problems in supplying towns and evacuating tourists.[28][29][30] District councils along the West Coast and in Canterbury have commissioned studies and begun preparations for an anticipated large earthquake on the Alpine Fault.[31][32]

 
Earthquake risk zones New Zealand. Until 2011, the lack of historical earthquakes on the Alpine Fault was interpreted as meaning lower risk.

History of research edit

In 1940, Harold Wellman found that the Southern Alps were associated with a fault line approximately 650 km (400 miles)[n 1] long.[33] The fault was officially named the Alpine Fault in 1942 as an extension of a previously mapped structure.[5] At the same time, Harold Wellman proposed the 480 kilometres (300 mi) lateral displacement on the Alpine Fault. This displacement was inferred by Wellman due in part to the similarity of rocks in Southland and Nelson on either side of the Alpine Fault. Lateral displacements of this magnitude could not be explained by pre-plate tectonics geology and his ideas were not initially widely accepted until 1956.[34] Wellman also proposed in 1964 that the Alpine Fault was a Cenozoic structure, which was in conflict with the older Mesozoic age accepted at the time. This idea coupled with the displacement on the fault proposed that the earth's surface was in relatively rapid constant movement and helped to overthrow the old geosynclinal hypothesis in favour of plate tectonics.[33]

In 1964 a 25-metre-long concrete wall was built across the fault to measure the fault's movements and to find if it moves slowly over time or suddenly during big earthquakes. The wall has not moved since being built, which indicates that the build up of energy is released suddenly during large earthquakes.[35][36]

Richard Norris and Alan Cooper from the Department of Geology, University of Otago conducted extensive research on the structure and petrology of the Alpine Fault respectively throughout the later 20th and early 21st centuries. It was during this time that the cyclicity of the Alpine Fault earthquakes and meaning of the increase in metamorphic grade towards the fault was discovered and refined.[37] Originally this regional increase in grade was inferred to be from frictional heating along the fault not uplift of deeper geological sequences. Richard H. Sibson from the same university also used the Alpine Fault to refine his nomenclature of fault rocks which gained international adherence.[38]

Deep Fault Drilling Project edit

The Deep Fault Drilling Project (DFDP) was an attempt in 2014 to retrieve rock and fluid samples and make geophysical measurements inside the Alpine Fault zone at depth.[39][40] It was a $2.5 million international research project designed to drill 1.3 km to the fault plan in two months.[40] The DFDP was the second project to try to drill an active fault zone and return samples after the San Andreas Fault Observatory at Depth.[40][41] One of the goals of the project was to use the deformed rocks from the fault zone to determine its resistance to stress.[40] Researchers also planned to install long term equipment for measuring pressure, temperature and seismic activity near the fault zone.[40] It was led by New Zealand geologists Rupert Sutherland, John Townsend and Virginia Toy and involves an international team from New Zealand, Canada, France, Germany, Japan, the United Kingdom, and the United States.[42]

In 2017, they reported they had discovered beneath Whataroa, a small township on the Alpine Fault, "extreme" hydrothermal activity which "could be commercially very significant".[16][43] One of the lead researchers said that it is likely to be globally unique.[44]

See also edit

Notes edit

  1. ^ a b c A former length quoted in the article introduction at 480 km, was noted on article review in May 2023 to be discordant with the length presently quoted in the reference used which is of 600 km. This source, while not an original academic work is an respected source so length was corrected back after further validation as explained in this note. It is quite possible that the reference was updated after the access date of 2018-12-31 or that the 480 km figure is actually the length of off set of the fault, inserted in easy to make error, and indeed the offset constrains the minimum length of the fault. It was further noted that another non academic reference to length of the fault used later in the article claimed a fault length of 850 km. This source, when checked was a press statement on research findings, so not peer-reviewed and is possibly from Nathan 2011 as source. It has been corrected too with context. Berryman's group started using a 800 km figure in their 2012 academic work, which is an increased length from Berryman et al. (1992). This gave a 650km length including the Wairau Fault which many workers do not include in the fault length. There is no evidence yet of full rupture including the Wairau Fault (see article). There is evidence for off shore full length fault rupture however as in the 1717 event. The 800 km length includes the Wairau Fault and assumes the off shore portion ends just south of Fiordland. The length of the fault will depend upon how much if any of the southern off shore portion is included or if the Wairau Fault is added. The GNS New Zealand Active Fault database maps about 520 km of fault on land or if the fault was a straight line end to end about 500 km. The total length of the South Island is about 800km for reference. Academic work on the fault does not always state its total length.

References edit

  1. ^ "GNS:New Zealand Active Faults Database". Retrieved 2023-04-29.
  2. ^ a b c d e f g h i Howarth, Jamie D.; Cochran, Ursula A.; Langridge, Robert M.; Clark, Kate; Fitzsimons, Sean J.; Berryman, Kelvin; Villamor, Pilar; Strong, Delia T. (2018). "Past large earthquakes on the Alpine Fault: paleoseismological progress and future directions". New Zealand Journal of Geology and Geophysics. 61 (3): 309–328. Bibcode:2018NZJGG..61..309H. doi:10.1080/00288306.2018.1464658. S2CID 134211005.
  3. ^ a b c d e Cochran, U.A.; Clark, K.J.; Howarth, J.D.; Biasi, G.P.; Langridge, R.M.; Villamor, P.; Berryman, K.R.; Vandergoes, M.J. (2017). "A plate boundary earthquake record from a wetland adjacent to the Alpine fault in New Zealand refines hazard estimates". Earth and Planetary Science Letters. 464: 175–188. Bibcode:2017E&PSL.464..175C. doi:10.1016/j.epsl.2017.02.026. ISSN 0012-821X.
  4. ^ a b c "Alpine Fault / Major Faults in New Zealand / Earthquakes / Science Topics / Learning / Home – GNS Science". www.gns.cri.nz. Retrieved 2023-10-11.
  5. ^ a b c d e Graham 2015, pp. 120.
  6. ^ "Research finds Alpine Fault quake more likely in the next 50 years, Our Science, 01 June 2021". www.gns.cri.nz. 1 June 2021. Retrieved 30 March 2024.
  7. ^ "Alpine Fault: Probability of damaging quake higher than previously thought". www.rnz.co.nz. 20 April 2021. Retrieved 3 December 2021.
  8. ^ Zachariasen, J.; Berryman, K.; Langridge, R.; Prentice, C.; Rymer, M.; Stirling, M.; Villamor, P. (2006). "Timing of late Holocene surface rupture of the Wairau Fault, Marlborough, New Zealand". New Zealand Journal of Geology and Geophysics. 49 (1): 159–174. Bibcode:2006NZJGG..49..159Z. doi:10.1080/00288306.2006.9515156.
  9. ^ Keep, Myra; Schellart, Wouter P. (2012). "Introduction to the thematic issue on the evolution and dynamics of the Indo-Australian plate". Australian Journal of Earth Sciences. 59, 2012 (6: THEMATIC ISSUE — Evolution and dynamics of the Indo-Australian plate): 807–808. Bibcode:2012AuJES..59..807K. doi:10.1080/08120099.2012.708360. S2CID 128996831.
  10. ^ a b c Graham, I. J. (2008). A Continent on the Move: New Zealand Geoscience Into the 21st Century. Geological Society of New Zealand. ISBN 978-1-877480-00-3.
  11. ^ a b Norris, Richard J.; Cooper, Alan F. (2001-02-03). "Late Quaternary slip rates and slip partitioning on the Alpine Fault, New Zealand". Journal of Structural Geology. 23 (2–3): 507–520. Bibcode:2001JSG....23..507N. doi:10.1016/S0191-8141(00)00122-X. ISSN 0191-8141.
  12. ^ Norris, Richard J. (2004). "Strain localisation within ductile shear zones beneath active faults: The Alpine Fault contrasted with the adjacent Otago fault system, New Zealand" (PDF). Earth, Planets and Space. 56 (12): 1095–1101. Bibcode:2004EP&S...56.1095N. doi:10.1186/BF03353328. S2CID 53613442.
  13. ^ Cooper, Alan F.; Norris, Richard J. (1995-02-01). "Origin of small-scale segmentation and transpressional thrusting along the Alpine fault, New Zealand". GSA Bulletin. 107 (2): 231–240. Bibcode:1995GSAB..107..231N. doi:10.1130/0016-7606(1995)107<0231:OOSSSA>2.3.CO;2. ISSN 0016-7606.
  14. ^ "Alpine Fault virtual field trip". University of Otago department of geology. Retrieved 5 July 2021.
  15. ^ Koons, P. O. (1987). "Some thermal and mechanical consequences of rapid uplift: an example from the Southern Alps, New Zealand". Earth and Planetary Science Letters. 86 (2–4): 307–319. Bibcode:1987E&PSL..86..307K. doi:10.1016/0012-821X(87)90228-7.
  16. ^ a b Sutherland, R.; Townend, J.; Toy, V.; Upton, P. and 62 others (1 June 2017). "Extreme hydrothermal conditions at an active plate-bounding fault". Nature. 546 (7656): 137–140. Bibcode:2017Natur.546..137S. doi:10.1038/nature22355. hdl:1874/351355. PMID 28514440. S2CID 205256017.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  17. ^ Graham 2015, pp. 120–121.
  18. ^ a b Barnes, Philip M.; Sutherland, Rupert; Davy, Bryan; Delteil, Jean (2001). "Rapid creation and destruction of sedimentary basins on mature strike-slip faults: an example from the offshore Alpine Fault, New Zealand". Journal of Structural Geology. 23 (11): 1727–1739. Bibcode:2001JSG....23.1727B. doi:10.1016/s0191-8141(01)00044-x. ISSN 0191-8141.
  19. ^ McLintock, Alexander Hare; Frank Foster Evison, M. A.; Taonga, New Zealand Ministry for Culture and Heritage Te Manatu. "Earthquakes and Faults". An encyclopaedia of New Zealand, edited by A. H. McLintock, 1966. Retrieved 2019-01-05.
  20. ^ Howarth, Jamie D.; Barth, Nicolas C.; Fitzsimons, Sean J.; Richards-Dinger, Keith; Clark, Kate J.; Biasi, Glenn P.; Cochran, Ursula A.; Langridge, Robert M.; Berryman, Kelvin R.; Sutherland, Rupert (2021). "Spatiotemporal clustering of great earthquakes on a transform fault controlled by geometry". Nature Geoscience. 14 (5): 314–320. Bibcode:2021NatGe..14..314H. doi:10.1038/s41561-021-00721-4. ISSN 1752-0894. S2CID 233304353.
  21. ^ Bunce, Michael; Beavan, Nancy R.; Oskam, Charlotte L.; Jacomb, Christopher; Allentoft, Morten E.; Holdaway, Richard N. (2014-11-07). "An extremely low-density human population exterminated New Zealand moa". Nature Communications. 5: 5436. Bibcode:2014NatCo...5.5436H. doi:10.1038/ncomms6436. ISSN 2041-1723. PMID 25378020.
  22. ^ a b "Alpine Fault". GNS Science. Retrieved 14 March 2018.
  23. ^ Booker, Jarrod (24 August 2006). "Deadly alpine quake predicted". The New Zealand Herald. Retrieved 18 January 2015.
  24. ^ a b Berryman, K.; Cooper, A.F.; Norris, R.J.; Villamor, P.; Sutherland, R.; Wright, T.; Schermer, E.R.; Langridge, R.; Biasi, G. (2012). "Late Holocene Rupture History of the Alpine Fault in South Westland, New Zealand". Bulletin of the Seismological Society of America. 102 (2): 620–638. Bibcode:2012BuSSA.102..620B. doi:10.1785/0120110177.
  25. ^ "'Well Behaved' Alpine Fault – experts respond". Science Media Centre. 28 June 2012. Retrieved 14 March 2018.
  26. ^ "New study says Alpine Fault quake interval shorter than thought: GNS Science". stuff www.stuff.co.nz. 6 March 2017. Retrieved 17 September 2018.
  27. ^ Goff, J.R.; Chague-Goff, C. (2001). "Catastrophic events in New Zealand coastal environments" (PDF). Conservation Advisory Science Notes No. 333. Department of Conservation / GeoEnvironmental Consultants. ISSN 1171-9834. Retrieved 14 September 2018.
  28. ^ "Videos show devastating impact across South Island if Alpine Fault ruptures". Stuff (Fairfax). 16 May 2018.
  29. ^ "Thousands to be evacuated, highways blocked for months when Alpine Fault ruptures". Stuff (Fairfax). 26 May 2018.
  30. ^ "South Island plan for the next Alpine Fault quake". Radio New Zealand. 2018-05-15. Retrieved 2019-01-05.
  31. ^ "Emergency Response Planning". AF8 (Alpine Fault Magnitude 8). Retrieved 2019-02-06.
  32. ^ (PDF). www.wcrc.govt.nz. 2006. Archived from the original (PDF) on 2018-02-01.
  33. ^ a b Nathan, S. (2011). "Harold Wellman and the Alpine Fault of New Zealand". Episodes. 34 (1): 51–56. doi:10.18814/epiiugs/2011/v34i1/008.
  34. ^ Wellman, H. w. (1956). "Structural outline of New Zealand (No. 121)". New Zealand Department of Scientific and Industrial Research, Wellington. 121 (4).
  35. ^ Carroll, Joanne (1 February 2016). "Scientists hunt for clues about big Alpine Fault quake". Stuff. Retrieved 12 April 2024.
  36. ^ "The wall that Frank built". New Zealand Geographic. Retrieved 2024-04-12.
  37. ^ Norris, Richard J.; Cooper, Alan F. (2003-12-01). "Very high strains recorded in mylonites along the Alpine Fault, New Zealand: implications for the deep structure of plate boundary faults". Journal of Structural Geology. 25 (12): 2141–2157. Bibcode:2003JSG....25.2141N. doi:10.1016/S0191-8141(03)00045-2. ISSN 0191-8141.
  38. ^ Atkinson, B. K.; White, S. H.; Sibson, R. H. (1981-01-01). "Structure and distribution of fault rocks in the Alpine Fault Zone, New Zealand". Geological Society, London, Special Publications. 9 (1): 197–210. Bibcode:1981GSLSP...9..197S. doi:10.1144/GSL.SP.1981.009.01.18. ISSN 2041-4927. S2CID 128426863.
  39. ^ Townend, John (2009). "Deep Fault Drilling Project—Alpine Fault, New Zealand" (PDF). Scientific Drilling. 8: 75–82. Bibcode:2009SciDr...8...75T. doi:10.5194/sd-8-75-2009.
  40. ^ a b c d e "Drilling into an active earthquake fault in New Zealand". phys.org. Retrieved 2019-02-16.
  41. ^ Ravilious, Kate (2005-12-10). "Why are scientists drilling into the San Andreas fault?". The Guardian. ISSN 0261-3077. Retrieved 2018-12-31.
  42. ^ "DEEP FAULT DRILLING PROJECT-2 FAQs / drill probe in Alpine Fault / Media Releases / News and Events / Home – GNS Science". www.gns.cri.nz. Retrieved 2018-12-31.
  43. ^ "Geothermal discovery on West Coast". Otago Daily Times. 18 May 2017.
  44. ^ Elder, Vaughan. "Geothermal discovery on West Coast". NZ Herald. ISSN 1170-0777. Retrieved 2018-12-30.

Sources edit

  • Graham, I. J. (2015). A Continent on the Move: New Zealand Geoscience Revealed. Geoscience Society of New Zealand. ISBN 9781877480478.
  • Robinson, R (2003). "Potential earthquake triggering in a complex fault network: the northern South Island, New Zealand". Geophysical Journal International. 159 (2): 734–748. doi:10.1111/j.1365-246x.2004.02446.x.
  • Wells, A.; Yetton, M.T.; Duncan, R.P.; and Stewart, G.H. (1999). Prehistoric dates of the most recent Alpine fault earthquakes, New Zealand. Geology, 27(11), 995–998. (abstract)

Further reading edit

  • Howarth, Jamie D.; Barth, Nicolas C.; Fitzsimons, Sean J.; Richards-Dinger, Keith; Clark, Kate J.; Biasi, Glenn P.; Cochran, Ursula A.; Langridge, Robert M.; Berryman, Kelvin R.; Sutherland, Rupert (2021). "Spatiotemporal clustering of great earthquakes on a transform fault controlled by geometry". Nature Geoscience. 14 (5): 314–320. Bibcode:2021NatGe..14..314H. doi:10.1038/s41561-021-00721-4. ISSN 1752-0894. S2CID 233304353.

External links edit

  • Alpine Fault earthquake talk 2014-08-08 at the Wayback MachineOtago Regional Council
  • Alpine Fault research in the Department of Geology – University of Otago
  • Where were New Zealand's largest earthquakes? – GNS Science
  • – Nature & Company Limited
  • The Next Alpine Fault Earthquake in New Zealand – GNS Science on YouTube
  • Deep Fault Drilling Programme

May 02, 2024
alpine, fault, geological, fault, that, runs, almost, entire, length, zealand, south, island, being, about, long, forms, boundary, between, pacific, plate, australian, plate, southern, alps, have, been, uplifted, fault, over, last, million, years, series, eart. The Alpine Fault is a geological fault that runs almost the entire length of New Zealand s South Island being about 600 km 370 mi n 1 long and forms the boundary between the Pacific Plate and the Australian Plate 4 The Southern Alps have been uplifted on the fault over the last 12 million years in a series of earthquakes However most of the motion on the fault is strike slip side to side with the Tasman district and West Coast moving north and Canterbury and Otago moving south The average slip rates in the fault s central region are about 38 mm 1 5 in a year very fast by global standards 5 The last major earthquake on the Alpine Fault was in about 1717 AD with a great earthquake magnitude of Mw8 1 0 1 2 The probability of another one occurring before 2068 was estimated at 75 percent in 2021 6 7 Alpine FaultMovement along the Alpine Fault is deforming the continent of Zealandia with the southern part on the Pacific Plate sliding past and slightly onto the northwest part on the Australian Plate Map of active Alpine Fault on land red Click on the map to enable mouse over of fault features 1 EtymologySouthern AlpsCountryNew ZealandRegionWest Coast and Southland RegionsCharacteristicsRangeSouthern AlpsLength600 km 370 mi StrikeNE SWDisplacement30 mm 1 2 in yrTectonicsPlateAustralian PacificStatusActiveEarthquakes1717 prehistoricTypeStrike slip faultMovementUp to Mw8 2 2 dextral convergent east side upAgeMiocene Holocene 12 0 0003 Ma 3 PreꞒ Ꞓ O S D C P T J K Pg NOrogenyKaikouraNew Zealand geology database includes faults Snow delineates the escarpment formed by the Alpine Fault along the Southern Alps north west edge near the South Island s west coast This satellite image shows the aftermath of a blizzard that hit the island in July 2003 Contents 1 Geographic extent and plate motion 2 Tectonics 3 Geological origin and evolution 4 Fault zone geology 5 Earthquakes 5 1 Prehistoric 5 2 Historic 5 3 Prediction of next earthquake 5 4 Projected effects of a rupture 6 History of research 6 1 Deep Fault Drilling Project 7 See also 8 Notes 9 References 9 1 Sources 10 Further reading 11 External linksGeographic extent and plate motion edit nbsp Map of the northern end of the Alpine Fault and Marlborough Fault System The Pacific Plate and Indo Australian Plate boundary forms the Macquarie Fault Zone in the Puysegur Trench off the southwestern corner of the South Island and comes onshore as the Alpine Fault just north of Milford Sound The Alpine Fault then runs the length of the South Island just west of the Southern Alps to near Lewis Pass in the central northern section of the island At this point it splits into a set of smaller faults known as the Marlborough Fault System This set of faults which includes the Wairau Fault the Hope Fault the Awatere Fault and the Clarence Fault transfer displacement between the Alpine Fault and the Hikurangi subduction zone to the north The Hope Fault is thought to represent the primary continuation of the Alpine Fault 8 Tectonics editThe Australian Plate which is in the process of again separating from the Indo Australian Plate 9 is subducting towards the east south of the South Island and the Pacific Plate is subducting towards the west to the north In the middle the Alpine Fault is a transform boundary and has both dextral right lateral strike slip movement and uplift on the southeastern side 2 The uplift is due to an element of convergence between the plates meaning that the fault has a significant high angle reverse oblique component to its displacement 4 10 In the northern section of the fault the transition to the Marlborough Fault System reflects transfer displacement between the mainly transform plate boundary of the Alpine fault and the mainly destructive boundary further northwards from the Hikurangi Subduction Zone to the Kermadec Trench The Alpine Fault has the greatest uplift of the Pacific Plate near Aoraki Mount Cook in its central section Here the relative motion between the two plates averages 37 40 mm a year This is distributed as 36 39 mm of horizontal and 6 10 mm upwards movement on the fault s plane per year 5 At the southern end of the fault there is effectively no uplift component of the Pacific Plate 11 and other faults in Fiordland the Otago fault system and in Canterbury such as the Ostler Fault Zone and those associated with the 7 1 MW Darfield earthquake share the strain as a result of the plate collision 12 The uplift in this South Westland region of the fault which has a dextral strike slip rate of about 28 mm 1 1 in year is on the Australian plate side of it and has meter scale vertical uplift every 290 years odd 3 Geological origin and evolution edit nbsp New Zealand before the activation of the Alpine Fault 30 Ma nbsp Outcrop showing hydrothermally altered cataclasite in green within the Alpine Fault zone Waikukupa River nbsp Alpine Fault outcrop showing banded cataclasite and breccia Waikukupa River Between 25 and 12 million years ago the movement on the proto Alpine Fault was exclusively strike slip The Southern Alps had not yet formed and most of New Zealand was covered in water 10 Then uplift slowly began as the plate motion became slightly oblique to the strike of the Alpine Fault In the last 12 million years the Southern Alps have been uplifted approximately 20 km 12 mi however as this has occurred more rain has been trapped by the mountains leading to more erosion 4 This along with isostatic constraints has kept the Southern Alps less than 4 000 m 13 000 ft high Uplift on the Alpine Fault has led to the exposure of deep metamorphic rocks near the fault within the Southern Alps This includes mylonites and the Alpine Schist which increases in metamorphic grade towards the fault The eroded material has formed the Canterbury Plains 10 The Alpine Fault is not a single structure but often splits into pure strike slip and dip slip components 11 13 Near the surface the fault can have multiple rupture zones 5 Fault zone geology editThe fault zone is exposed at numerous locations along the West Coast 14 and typically consists of a 10 to 50 m wide fault gouge zone 2 with pervasive hydrothermal alteration This last is because water penetrates down to up to 6 km 3 7 mi through hot rock associated with the fault The water then can arise in hot springs with temperatures of over 50 C 122 F in the fault valley 15 although the temperature of the water at depth is much more extreme 16 Most of the movement along the fault occurs in this zone 5 In outcrop the fault zone is overlain by mylonites which formed at depth and have been uplifted by the fault 17 A structural study 18 of a segment of the Alpine Fault to the southwest of Fiordland examined the Dagg Basin an offshore sedimentary basin at 3 000 m 9 800 ft depth Basin sediments are primarily from Pleistocene glaciation and structures within them reveal a past complexity that is no longer present in the basin The current structure is a pull apart basin along a releasing bend in the Alpine Fault with a segment of inverted basin along the southern edge due to transpression The study discussed the short lived nature of the releasing bend on the order of 105 to 106 years during which there were 450 1650 m of dextral displacement The nature of the displacement served as an example of the kinds of ephemeral structures that can develop along a mature strike slip fault system 18 Earthquakes editThere have been no major historical earthquakes on the Alpine Fault Because of this during the mid 20th century it was speculated that the Alpine Fault creeps without making large earthquakes 19 However it is now inferred by multiples lines of evidence that the Alpine Fault ruptures creating major earthquakes approximately every few hundred years The last whole fault rupture event was in 1717 and is now known to have been a great earthquake of Mw 8 1 0 1 2 There is also fair evidence for a post 1717 event confined to North Westland section of the fault but the date is unclear 2 There are two modes of large earthquake behaviour with either major MW 7 8 or great MW gt 8 earthquakes and predicting the next mode is a challenge as these appear to evolve over multiple seismic cycles in response to along strike differences in geometry 20 Prehistoric edit The Maori arrived in New Zealand c 1300 but never reached a high population density in the colder South Island 21 Therefore while earthquakes are an important part of Maori oral tradition no stories have been passed down about South Island earthquakes Over the last thousand years the major ruptures along the Alpine Fault causing earthquakes of about magnitude 8 had previously been determined to have occurred at least four times 22 These had separation of between 100 and 350 years 22 The 1717 quake appeared to have involved a rupture along nearly 400 kilometres 250 mi of the southern two thirds of the fault Scientists say that a similar earthquake could happen at any time as the interval since 1717 is longer than the intervals between the earlier events 23 Newer research carried out by the University of Otago the Australian Nuclear Science and Technology Organisation and others has revised the dates and nature of the earthquakes and given greater understanding of their number Studies at Haast towards the centre of the fault only identified three major rupture events in the last 1000 years 24 Studies at the far southern end identified seven events in the last 2000 years and the most southern 20 km 12 mi of the fault has had 27 events since 6000 BCE 3 This information has been updated with better dating techniques and is summarised in the following timeline for the various sections of the fault 2 This work suggests that large fault ruptures occurred in 1717 about 1400 about 1100 and about 390 CE 2 Historic edit There have been no major earthquakes on the Alpine Fault in historic times its southern and northern offshoots have however experienced sizable earthquakes 1929 Arthur s Pass estimated magnitude 7 1 1929 Murchison estimated magnitude 7 8 1968 Inangahua estimated magnitude 7 1 2003 Fiordland estimated magnitude 7 1 2009 Fiordland estimated magnitude 7 8 Prediction of next earthquake edit In 2012 GNS Science researchers published an 8000 year timeline of 24 major earthquakes on the southern end of the fault from sediments at Hokuri Creek near Lake McKerrow in north Fiordland In earthquake terms the up to 800 kilometres 500 mi n 1 long 24 fault was remarkably consistent rupturing on average every 330 years at intervals ranging from 140 years to 510 years 25 In 2017 GNS researchers revised the figures after they combined updated Hokuri site records with a thousand year record from another site 20 km away at John O Groats River to produce a record of 27 major earthquake events during the 8000 year period 3 This gave a mean recurrence rate of 291 years plus or minus 23 years 3 versus the previously estimated rate of 329 years plus or minus 26 years In the new study the interval between earthquakes ranged from 160 to 350 years and the probability of an earthquake occurring in the 50 years following 2017 was estimated at 29 percent for this southern sector of the fault alone 26 2 Projected effects of a rupture editLarge ruptures can also trigger earthquakes on the faults continuing north from the Alpine Fault There is paleotsunami evidence of near simultaneous ruptures of the Alpine Fault and Wellington and or other major faults to the north having occurred at least twice in the past 1 000 years 27 A 2018 study says that a significant rupture in the Alpine Fault could lead to roads particularly in or to the West Coast being blocked for months as with the 2016 Kaikōura earthquake with problems in supplying towns and evacuating tourists 28 29 30 District councils along the West Coast and in Canterbury have commissioned studies and begun preparations for an anticipated large earthquake on the Alpine Fault 31 32 nbsp Earthquake risk zones New Zealand Until 2011 the lack of historical earthquakes on the Alpine Fault was interpreted as meaning lower risk History of research editIn 1940 Harold Wellman found that the Southern Alps were associated with a fault line approximately 650 km 400 miles n 1 long 33 The fault was officially named the Alpine Fault in 1942 as an extension of a previously mapped structure 5 At the same time Harold Wellman proposed the 480 kilometres 300 mi lateral displacement on the Alpine Fault This displacement was inferred by Wellman due in part to the similarity of rocks in Southland and Nelson on either side of the Alpine Fault Lateral displacements of this magnitude could not be explained by pre plate tectonics geology and his ideas were not initially widely accepted until 1956 34 Wellman also proposed in 1964 that the Alpine Fault was a Cenozoic structure which was in conflict with the older Mesozoic age accepted at the time This idea coupled with the displacement on the fault proposed that the earth s surface was in relatively rapid constant movement and helped to overthrow the old geosynclinal hypothesis in favour of plate tectonics 33 In 1964 a 25 metre long concrete wall was built across the fault to measure the fault s movements and to find if it moves slowly over time or suddenly during big earthquakes The wall has not moved since being built which indicates that the build up of energy is released suddenly during large earthquakes 35 36 Richard Norris and Alan Cooper from the Department of Geology University of Otago conducted extensive research on the structure and petrology of the Alpine Fault respectively throughout the later 20th and early 21st centuries It was during this time that the cyclicity of the Alpine Fault earthquakes and meaning of the increase in metamorphic grade towards the fault was discovered and refined 37 Originally this regional increase in grade was inferred to be from frictional heating along the fault not uplift of deeper geological sequences Richard H Sibson from the same university also used the Alpine Fault to refine his nomenclature of fault rocks which gained international adherence 38 Deep Fault Drilling Project edit The Deep Fault Drilling Project DFDP was an attempt in 2014 to retrieve rock and fluid samples and make geophysical measurements inside the Alpine Fault zone at depth 39 40 It was a 2 5 million international research project designed to drill 1 3 km to the fault plan in two months 40 The DFDP was the second project to try to drill an active fault zone and return samples after the San Andreas Fault Observatory at Depth 40 41 One of the goals of the project was to use the deformed rocks from the fault zone to determine its resistance to stress 40 Researchers also planned to install long term equipment for measuring pressure temperature and seismic activity near the fault zone 40 It was led by New Zealand geologists Rupert Sutherland John Townsend and Virginia Toy and involves an international team from New Zealand Canada France Germany Japan the United Kingdom and the United States 42 In 2017 they reported they had discovered beneath Whataroa a small township on the Alpine Fault extreme hydrothermal activity which could be commercially very significant 16 43 One of the lead researchers said that it is likely to be globally unique 44 See also editGeology of New Zealand List of earthquakes in New Zealand San Andreas FaultNotes edit a b c A former length quoted in the article introduction at 480 km was noted on article review in May 2023 to be discordant with the length presently quoted in the reference used which is of 600 km This source while not an original academic work is an respected source so length was corrected back after further validation as explained in this note It is quite possible that the reference was updated after the access date of 2018 12 31 or that the 480 km figure is actually the length of off set of the fault inserted in easy to make error and indeed the offset constrains the minimum length of the fault It was further noted that another non academic reference to length of the fault used later in the article claimed a fault length of 850 km This source when checked was a press statement on research findings so not peer reviewed and is possibly from Nathan 2011 as source It has been corrected too with context Berryman s group started using a 800 km figure in their 2012 academic work which is an increased length from Berryman et al 1992 This gave a 650km length including the Wairau Fault which many workers do not include in the fault length There is no evidence yet of full rupture including the Wairau Fault see article There is evidence for off shore full length fault rupture however as in the 1717 event The 800 km length includes the Wairau Fault and assumes the off shore portion ends just south of Fiordland The length of the fault will depend upon how much if any of the southern off shore portion is included or if the Wairau Fault is added The GNS New Zealand Active Fault database maps about 520 km of fault on land or if the fault was a straight line end to end about 500 km The total length of the South Island is about 800km for reference Academic work on the fault does not always state its total length References edit GNS New Zealand Active Faults Database Retrieved 2023 04 29 a b c d e f g h i Howarth Jamie D Cochran Ursula A Langridge Robert M Clark Kate Fitzsimons Sean J Berryman Kelvin Villamor Pilar Strong Delia T 2018 Past large earthquakes on the Alpine Fault paleoseismological progress and future directions New Zealand Journal of Geology and Geophysics 61 3 309 328 Bibcode 2018NZJGG 61 309H doi 10 1080 00288306 2018 1464658 S2CID 134211005 a b c d e Cochran U A Clark K J Howarth J D Biasi G P Langridge R M Villamor P Berryman K R Vandergoes M J 2017 A plate boundary earthquake record from a wetland adjacent to the Alpine fault in New Zealand refines hazard estimates Earth and Planetary Science Letters 464 175 188 Bibcode 2017E amp PSL 464 175C doi 10 1016 j epsl 2017 02 026 ISSN 0012 821X a b c Alpine Fault Major Faults in New Zealand Earthquakes Science Topics Learning Home GNS Science www gns cri nz Retrieved 2023 10 11 a b c d e Graham 2015 pp 120 Research finds Alpine Fault quake more likely in the next 50 years Our Science 01 June 2021 www gns cri nz 1 June 2021 Retrieved 30 March 2024 Alpine Fault Probability of damaging quake higher than previously thought www rnz co nz 20 April 2021 Retrieved 3 December 2021 Zachariasen J Berryman K Langridge R Prentice C Rymer M Stirling M Villamor P 2006 Timing of late Holocene surface rupture of the Wairau Fault Marlborough New Zealand New Zealand Journal of Geology and Geophysics 49 1 159 174 Bibcode 2006NZJGG 49 159Z doi 10 1080 00288306 2006 9515156 Keep Myra Schellart Wouter P 2012 Introduction to the thematic issue on the evolution and dynamics of the Indo Australian plate Australian Journal of Earth Sciences 59 2012 6 THEMATIC ISSUE Evolution and dynamics of the Indo Australian plate 807 808 Bibcode 2012AuJES 59 807K doi 10 1080 08120099 2012 708360 S2CID 128996831 a b c Graham I J 2008 A Continent on the Move New Zealand Geoscience Into the 21st Century Geological Society of New Zealand ISBN 978 1 877480 00 3 a b Norris Richard J Cooper Alan F 2001 02 03 Late Quaternary slip rates and slip partitioning on the Alpine Fault New Zealand Journal of Structural Geology 23 2 3 507 520 Bibcode 2001JSG 23 507N doi 10 1016 S0191 8141 00 00122 X ISSN 0191 8141 Norris Richard J 2004 Strain localisation within ductile shear zones beneath active faults The Alpine Fault contrasted with the adjacent Otago fault system New Zealand PDF Earth Planets and Space 56 12 1095 1101 Bibcode 2004EP amp S 56 1095N doi 10 1186 BF03353328 S2CID 53613442 Cooper Alan F Norris Richard J 1995 02 01 Origin of small scale segmentation and transpressional thrusting along the Alpine fault New Zealand GSA Bulletin 107 2 231 240 Bibcode 1995GSAB 107 231N doi 10 1130 0016 7606 1995 107 lt 0231 OOSSSA gt 2 3 CO 2 ISSN 0016 7606 Alpine Fault virtual field trip University of Otago department of geology Retrieved 5 July 2021 Koons P O 1987 Some thermal and mechanical consequences of rapid uplift an example from the Southern Alps New Zealand Earth and Planetary Science Letters 86 2 4 307 319 Bibcode 1987E amp PSL 86 307K doi 10 1016 0012 821X 87 90228 7 a b Sutherland R Townend J Toy V Upton P and 62 others 1 June 2017 Extreme hydrothermal conditions at an active plate bounding fault Nature 546 7656 137 140 Bibcode 2017Natur 546 137S doi 10 1038 nature22355 hdl 1874 351355 PMID 28514440 S2CID 205256017 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint numeric names authors list link Graham 2015 pp 120 121 a b Barnes Philip M Sutherland Rupert Davy Bryan Delteil Jean 2001 Rapid creation and destruction of sedimentary basins on mature strike slip faults an example from the offshore Alpine Fault New Zealand Journal of Structural Geology 23 11 1727 1739 Bibcode 2001JSG 23 1727B doi 10 1016 s0191 8141 01 00044 x ISSN 0191 8141 McLintock Alexander Hare Frank Foster Evison M A Taonga New Zealand Ministry for Culture and Heritage Te Manatu Earthquakes and Faults An encyclopaedia of New Zealand edited by A H McLintock 1966 Retrieved 2019 01 05 Howarth Jamie D Barth Nicolas C Fitzsimons Sean J Richards Dinger Keith Clark Kate J Biasi Glenn P Cochran Ursula A Langridge Robert M Berryman Kelvin R Sutherland Rupert 2021 Spatiotemporal clustering of great earthquakes on a transform fault controlled by geometry Nature Geoscience 14 5 314 320 Bibcode 2021NatGe 14 314H doi 10 1038 s41561 021 00721 4 ISSN 1752 0894 S2CID 233304353 Bunce Michael Beavan Nancy R Oskam Charlotte L Jacomb Christopher Allentoft Morten E Holdaway Richard N 2014 11 07 An extremely low density human population exterminated New Zealand moa Nature Communications 5 5436 Bibcode 2014NatCo 5 5436H doi 10 1038 ncomms6436 ISSN 2041 1723 PMID 25378020 a b Alpine Fault GNS Science Retrieved 14 March 2018 Booker Jarrod 24 August 2006 Deadly alpine quake predicted The New Zealand Herald Retrieved 18 January 2015 a b Berryman K Cooper A F Norris R J Villamor P Sutherland R Wright T Schermer E R Langridge R Biasi G 2012 Late Holocene Rupture History of the Alpine Fault in South Westland New Zealand Bulletin of the Seismological Society of America 102 2 620 638 Bibcode 2012BuSSA 102 620B doi 10 1785 0120110177 Well Behaved Alpine Fault experts respond Science Media Centre 28 June 2012 Retrieved 14 March 2018 New study says Alpine Fault quake interval shorter than thought GNS Science stuff www stuff co nz 6 March 2017 Retrieved 17 September 2018 Goff J R Chague Goff C 2001 Catastrophic events in New Zealand coastal environments PDF Conservation Advisory Science Notes No 333 Department of Conservation GeoEnvironmental Consultants ISSN 1171 9834 Retrieved 14 September 2018 Videos show devastating impact across South Island if Alpine Fault ruptures Stuff Fairfax 16 May 2018 Thousands to be evacuated highways blocked for months when Alpine Fault ruptures Stuff Fairfax 26 May 2018 South Island plan for the next Alpine Fault quake Radio New Zealand 2018 05 15 Retrieved 2019 01 05 Emergency Response Planning AF8 Alpine Fault Magnitude 8 Retrieved 2019 02 06 Buller District Council Lifelines Study Alpine Fault Earthquake Scenario PDF www wcrc govt nz 2006 Archived from the original PDF on 2018 02 01 a b Nathan S 2011 Harold Wellman and the Alpine Fault of New Zealand Episodes 34 1 51 56 doi 10 18814 epiiugs 2011 v34i1 008 Wellman H w 1956 Structural outline of New Zealand No 121 New Zealand Department of Scientific and Industrial Research Wellington 121 4 Carroll Joanne 1 February 2016 Scientists hunt for clues about big Alpine Fault quake Stuff Retrieved 12 April 2024 The wall that Frank built New Zealand Geographic Retrieved 2024 04 12 Norris Richard J Cooper Alan F 2003 12 01 Very high strains recorded in mylonites along the Alpine Fault New Zealand implications for the deep structure of plate boundary faults Journal of Structural Geology 25 12 2141 2157 Bibcode 2003JSG 25 2141N doi 10 1016 S0191 8141 03 00045 2 ISSN 0191 8141 Atkinson B K White S H Sibson R H 1981 01 01 Structure and distribution of fault rocks in the Alpine Fault Zone New Zealand Geological Society London Special Publications 9 1 197 210 Bibcode 1981GSLSP 9 197S doi 10 1144 GSL SP 1981 009 01 18 ISSN 2041 4927 S2CID 128426863 Townend John 2009 Deep Fault Drilling Project Alpine Fault New Zealand PDF Scientific Drilling 8 75 82 Bibcode 2009SciDr 8 75T doi 10 5194 sd 8 75 2009 a b c d e Drilling into an active earthquake fault in New Zealand phys org Retrieved 2019 02 16 Ravilious Kate 2005 12 10 Why are scientists drilling into the San Andreas fault The Guardian ISSN 0261 3077 Retrieved 2018 12 31 DEEP FAULT DRILLING PROJECT 2 FAQs drill probe in Alpine Fault Media Releases News and Events Home GNS Science www gns cri nz Retrieved 2018 12 31 Geothermal discovery on West Coast Otago Daily Times 18 May 2017 Elder Vaughan Geothermal discovery on West Coast NZ Herald ISSN 1170 0777 Retrieved 2018 12 30 Sources edit Graham I J 2015 A Continent on the Move New Zealand Geoscience Revealed Geoscience Society of New Zealand ISBN 9781877480478 Robinson R 2003 Potential earthquake triggering in a complex fault network the northern South Island New Zealand Geophysical Journal International 159 2 734 748 doi 10 1111 j 1365 246x 2004 02446 x Wells A Yetton M T Duncan R P and Stewart G H 1999 Prehistoric dates of the most recent Alpine fault earthquakes New Zealand Geology 27 11 995 998 abstract Further reading editHowarth Jamie D Barth Nicolas C Fitzsimons Sean J Richards Dinger Keith Clark Kate J Biasi Glenn P Cochran Ursula A Langridge Robert M Berryman Kelvin R Sutherland Rupert 2021 Spatiotemporal clustering of great earthquakes on a transform fault controlled by geometry Nature Geoscience 14 5 314 320 Bibcode 2021NatGe 14 314H doi 10 1038 s41561 021 00721 4 ISSN 1752 0894 S2CID 233304353 External links editAlpine Fault earthquake talk Archived 2014 08 08 at the Wayback Machine Otago Regional Council Alpine Fault research in the Department of Geology University of Otago Where were New Zealand s largest earthquakes GNS Science Earthquakes and Tectonics in New Zealand Nature amp Company Limited The Next Alpine Fault Earthquake in New Zealand GNS Science on YouTube Deep Fault Drilling Programme Retrieved from https en wikipedia org w index php title Alpine Fault amp oldid 1219012754, wikipedia, wiki, book, books, library,

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