North Island Fault System

The North Island Fault System (NIFS) (also known as North Island Dextral Fault Belt or North Island Shear Belt[1]) is a set of southwest–northeast trending seismically-active faults in the North Island of New Zealand that carry most of the dextral (right lateral) strike-slip component of the oblique convergence of the Pacific Plate with the Australian Plate.

North Island Fault System
North Island Shear Belt, NIFS, North Island Dextral Fault Belt,
Major active fault zones of New Zealand for orientation (North Island Fault System is labelled) and to show variation in displacement vector of Pacific Plate relative to the Kermadec Plate and Australian Plate along the boundary. The Kermadec Trench label would better read Hikurangi Trench at this position. The Kermadec Plate is not labelled but lies between the labels of the North Island Fault System and the Kermadec Trench in the picture.
Main active strands of the North Island Fault System
EtymologyNorth Island
CountryNew Zealand
RegionNorth Island
Characteristics
Length200 km (120 mi)
Displacement1 cm (0.39 in)/yr
Tectonics
PlateIndo-Australian
StatusActive
Typestrike-slip
Movement8.2,Mw
AgeMiocene-Holocene
New Zealand Active Fault database

The faults include the Wairarapa Fault and Wellington Fault to the southwest, the Ruahine and Mohaka Faults in the central section and the Waimana, Waiotahi, Whakatane and Waiohau Faults to the northeast. Most of the fault system consists of dextral strike-slip faults, although towards its northeastern end the trend swings to more S-N trend and the faults become mainly oblique normal in sense as the zone intersects with the Taupō Rift. This fault zone accommodates up to 10 mm/yr of strike-slip displacement.[2]

Faults

The North Island Fault System consists of eight main fault strands and many smaller related faults that are also currently active.

Mohaka Fault

The more southeasterly branch of the Wellington Fault is known as the Mohaka fault. The fault splays to the north, onto the Waimana Fault, which itself has branches of the Waiotahi and Waioeka Faults. The Waimana Fault is 50 km (31 mi) long with potential for a 6.9 MW shock at its recurrence interval of 2850 years and slip rate of 0.7 mm (0.028 in)/year.[3] The main segment of the Mohaka Fault eventually passes into the Whakatane Fault which has an off shore extension.[2] The Whakatane Fault has multisegment capacity for a size 7 MW earthquake at a recurrence interval of 3000 years and slip rate of 1 mm (0.039 in).[3] To the east of the Mohaka Fault is the Patoka Fault which commences in the Tutaekuri River valley within 500 m (1,600 ft) of a Mohaka Fault splay.[4] Where the Potaka Fault intercepts the Esk Forest its most eastern active splay becomes the Rukumoana Fault.[4] The Potaka Fault terminates just south of the peak Tauwhare Papauma on State Highway 5.[4] The Rukumoana Fault has an active northern splay called the Rangiora Fault and both terminate in the region of Hawke's Bay north of Lake Tutira.[4] Where the Rangiora Fault terminates the Waiotahi Fault to its north by about 20 km (12 mi) becomes the most eastern active fault in the system.[4]

Ruahine Fault

As the Wellington Fault branches near Woodville, the more northwesterly branch is known as the Ruahine Fault. Results from trenching over this fault suggest an earthquake recurrence interval of 400500 years, with typical offsets in the range 3.05.5 m.[5]

At its northern end this fault becomes the Waiohau Fault which has several geologically active splays.[2] There is a western splay of the Ruahine Fault before this to the Kaweka Fault around the Mohaka River valley.[4] The Kaweka Fault remains the most western fault until it becomes in turn the Wheao Fault in the Waipunga River valley.[4] The Te Whaiti Fault is a splay towards the NNE of the Wheao Fault that rejoins it near Murupara and for a brief while the Te Whaiti Fault is the most western active fault of the system before it merges with a splay of the Waiohau Fault which terminates at the head of the Rangitaiki River valley.[4]

Waimana Fault

The Waimana Fault is to the east of the Whakatane Fault both of which join the Mohaka Fault in the south of the system[2] To its north it has an off shore portion that terminates against the White Island Fault which is the eastern margin of the Taupō Rift.[6]

Waiohau Fault

The Waiohau Fault extends from the end of the Ruahine Fault north towards the Bay of Plenty for 61 km (38 mi).[3] The slip rate is 1.4 mm (0.055 in)/year with estimated movement of a multisegment fault rupture of 7.1 MW with an average recurrence of 3000 years.[3] It lies roughly parallel with, and to the west of, the Whakatane, Waimana, and Waiotahi Faults, and to the east of the Taupo Rift. At its southern end it is a dextral strike-slip fault, becoming a normal dip-slip fault for the northern part of its length. The valley of the Rangitaiki River approximately follows the line of the fault. It terminates against the eastern margin of the Taupō Rift in the on shore portion of the Whakatāne Graben.[7] The fault is believed to be responsible for an earthquake in 1866 which was centred near Te Mahoe, east of Kawerau.[8][9]

Waiotahi Fault

The Waiotahi Fault commences near the end of the Mangahopai Road in Hawkes Bay and extends as the most eastern active fault in the system through the western aspects of Lake Waikaremoana. It then has an eastern splay, the Koranga Fault just north of the peak Tataemakora while itself continuing all the way via the coast west of Opotiki to terminate off shore where it intercepts the White Island Fault of the Taupō Rift.[4] The Karanga Fault terminates in the mountains 20 km (12 mi) south of Opotiki.[4]

Wairarapa Fault
Main article: Wairarapa Fault

The Wairarapa Fault extends from near the coast just southwest of Lake Wairarapa, running along the lake's northwestern edge. The 8.2 Mw 1855 Wairarapa earthquake was caused by movement along this fault. The recurrence interval for large earthquakes on this fault is less than 2,000 years.[10]

Wellington Fault
Main article: Wellington Fault

The Wellington Fault is a dextral strike-slip fault that runs from the Cook Strait on the southern coast of North Island up to near Woodville, where the fault branches into the Mohaka and Ruahine Faults. No historical earthquakes have been recorded along this fault although a significant event is estimated to have occurred within the last 1,000 years. The recurrence interval for large earthquakes on this fault is estimated to be less than 2,000 years.[10] Three main segments have been identified, the Wellington-Hutt section, the Tararua section and the Pahiatua section.[11][12]

Whakatane Fault

The Whakatane Fault is where the North Island Fault System intersects the Taupo Rift[2] and so displacement across the Whakatane Fault is expected to be oblique, with both normal dip-slip (1.5 ± 0.5 mm/yr) and right-lateral strike-slip (1.1 ± 0.5 mm/yr) components of motion.[13] The known three surface-rupturing prehistoric earthquakes over the last 10,000 years were associated with net slip at the ground surface of about 3 m (9.8 ft).[13]

References
  1. Taylor, Susanna K. A Long Timescale High-Resolution Fault Activity History of the Whakatane Graben, Bay of Plenty, New Zealand (PhD thesis Graduate School of the Southampton Oceanography Centre) (PDF) (Thesis). Retrieved 2023-04-04.
  2. Mouslopoulou, V.; Nicol, A.; Little, T.A.; Begg J.A. (2009). "Palaeoearthquake surface rupture in a transition zone from strike-slip to oblique-normal slip and its implications to seismic hazard, North Island Fault System, New Zealand". In Reicherter K., Michetti A.M. & Silva P.G. (ed.). Palaeoseismology: historical and prehistorical records of earthquake ground effects for seismic hazard assessment. Special Publications. Vol. 316. London: Geological Society. pp. 269–292. ISBN 978-1-86239-276-2.
  3. Perrin, N D (1999). "Earthquake Hazards of the Bay of Plenty - Update to 1999". New Zealand Institute of Geological and Nuclear Sciences. Retrieved 2023-04-10.
  5. Neall, V.E.; Hanson J.A. "The Neotectonics of the Ruahine and Mohaka Faults, between the Manawatu Gorge and Puketitiri and Figures to Accompany Final Prog". Research Paper 971. Earthquake Commission. Retrieved 6 October 2010.
  6. Wright, C. (1990). "Late Quaternary faulting of the offshore Whakatane Graben, Taupo Volcanic Zone, New Zealand". New Zealand Journal of Geology and Geophysics. 33 (2): 245–256. doi:10.1080/00288306.1990.10425682.
  7. Nairn, IA; Beanland, S (1989). "Geological setting of the 1987 Edgecumbe earthquake, New Zealand". New Zealand Journal of Geology and Geophysics. 32 (1): 1–3. doi:10.1080/00288306.1989.10421383.
  8. "New Zealand Journal of Geology and Geophysics". February 1958.
  9. Mouslopoulou, V.; Nicol, A.; Walsh, J. J.; Beetham, D.; Stagpoole, V. (2008). "Quaternary temporal stability of a regional strike-slip and rift fault intersection". Journal of Structural Geology. 30 (4): 451–463. CiteSeerX 10.1.1.544.6090. doi:10.1016/j.jsg.2007.12.005.
  10. NGS Science. "New Zealand Active Faults Database". Archived from the original on 29 September 2010. Retrieved 4 October 2010.
  11. Langridge, R.M.; Berryman K.R.; van Dissen R.J. (2005). "Defining the geometric segmentation and Holocene slip rate of the Wellington Fault, New Zealand: the Pahiatua section". New Zealand Journal of Geology & Geophysics. 48 (4): 591–607. doi:10.1080/00288306.2005.9515136. S2CID 128429946.
  12. Van Dissen, R.J.; Berryman, K.R. (1996). "Surface rupture earthquakes over the last ~1000 years in the Wellington region, New Zealand, and implications for ground shaking hazard". Journal of Geophysical Research: Solid Earth. 101 (B3): 5999–6019. Bibcode:1996JGR...101.5999V. doi:10.1029/95jb02391. Retrieved 4 October 2010.
  13. "Finding the concealed section of the Whakatane Fault in the Whakatane Township with a shear waveland streamer system: A seismic surveying report" (PDF). 2016. Retrieved 2022-08-29.
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