Wishbone Scarp
To the east of the eastern scarp are the very deep Pacific mid ocean basins, while to the west of the western scarp we have the shallower but currently very tectonically active Hikurangi Margin.
Geology
To its north it can be related to the Manihiki Plateau which has a water depth between 2.5 km (1.6 mi) to 3 km (1.9 mi), with the East Manihiki scarp which is a ridge that is up to 600 m (2,000 ft) above the Manihiki Plateau and falls to its east at least 2 km (1.2 mi) to the Penryhn Basin. The Manihiki scarp is usually interpreted as a continuation of the Wishbone scarp so the name Wishbone-East Manihiki scarp has been sometimes used.
The Wishbone scarp divides north of the Louisville Ridge at about 32°S into an eastern branch that continues the essentially north south orientation (163°) and a western branch that trends south west. These two branches mean the total trace length of the scarp structure is over 2,000 km (1,200 mi). Both pass through the Louisville hotspot chain, and in so doing lose some continuity but the western Wishbone scarp can be mapped all the way to the continental crust of the north east Chatham Rise. The Louisville Ridge seamounts show no compositional change as they cross the scarps but the East Wishbone scarp crossing point is associated with a distinct decrease in the volume of the younger seamount eruptives from that point east into the Pacific Plate. Near the Chatham Rise, which is continental crust, seismic reflection studies of the West Wishbone scarp shows two to three southeast facing tilted-block ridges which climb up to the Chatham Rise crest. The oceanic crust igneous bedrock here, just to the scarp's southeast is more than 86 million years old. Its composition is similar to those in intraoceanic subduction zone settings and quite distinct from that of mid-ocean ridges or other intraplate oceanic volcanoes. The scarp in this region can rise up to 1,800 m (5,900 ft) above surrounding sea floor.
The recent definite ability to assign its southern Western Wishbone scarp portion to primarily a dextral strike-slip fault that was active in the Late Cretaceous makes a fracture zone origin more likely for the entire scarp as the Eastern Wishborn scarp had already been characterised as a Cretaceous fracture zone. There were historically several possible tectonic explanations for its structure with it variously interpreted as related to a former fracture zone, an historic intraoceanic arc or a fossil (that is inactive) spreading center, with it being either a strike-slip plate boundary or a paleo-spreading ridge. The Cretaceous oceanic crust west of the scarps is the southern flank of an historic rise that had the now fossil Osbourn Trough as its spreading axis.
Tectonics
The breakup of Gondwana, and resulting forces on the former Phoenix Plate as the large igneous province of the Ontong Java–Manihiki–Hikurangi plateau split up, with separation into what are now the Manihiki and Hikurangi plateaus, are likely key to the formation of the Wishbone scarp. Rifting about 116 million years ago created the eastern margin of the Manihiki Plateau, the Manihiki Scarp, and separated the Manihiki and Hikurangi plateaus. Associated with this split, an east west trending rift system, now inactive, since at least 71 million years ago, but more likely before 84 million years ago, had developed and this is represented by the Osborn Trough in the Pacific sea floor, east of the Kermadec Trench. The Hikurangi Plateau initially subducted under onshore continental crust, but this process stalled between 105 and 100 million years ago and rotation started to occur which has led to the present and still active young geology of New Zealand. The Osborn Trough eastern end intercepts the definitive northern end of the Wishbone scarp, although it appears related tectonically to the Manihiki scarp to its north. At its southern end, the West Wishbone scarp matches the eastern border of the Hikurangi Plateau, which as part of the continental crust of Zealandia lies east of, and beneath, New Zealand, and the Chatham Rise.
As already has been said the East Wishbone Ridge had been characterised as a Cretaceous fracture zone as it separated domains of the Pacific Plate and there was fair geological understanding, particularly with regard to crustal age, due to studies along the line of the Louisville hotspot that crossed the East Wishbone scarp almost at right angles.
The gravity signature of the West Wishbone scarp, although fully consistent with a fault zone, looked similar to that of stalled spreading ridges west of the Antarctic Peninsula and in the west Scotia Sea, so it had been suggested that this was a rift valley of such a spreading ridge that stalled outboard of the trench. However, once it was realised that far to the north the Osbourn Trough was an extinct spreading ridge the geometry did not fit so this possibility became unlikely. The various different lava compositions along the West Wishbone scarp had raised the possibility that it had a composite history starting out as an intra-oceanic fracture zone prior to 115 million years ago, then became a subduction arc, and more recently a rift system.
Strike-slip motion along the West Wishbone scarp initiated as a consequence of the slowing of spreading at the Osbourn Trough about 105 million years ago. The West Wishbone scarp propagated along the eastern margin of the Hikurangi Plateau in response to this slowing at the same time that spreading continued unabated east of the East Wishbone Ridge. For a period there was short-lived, oblique subduction beneath the southern West Wishbone scarp but the scarp became tectonically inactive probably at the same time as the cessation of Osbourn Trough spreading.
See also
References
- ^ Mortimer et al. 2019, Figure 1
- ^ Mortimer et al. 2006, p185
- ^ Ai et al. 2008, p13
- ^ Larson et al. 2002, p15
- ^ Larson et al. 2002, p16
- ^ Worthington, Tim J.; Hekinian, Roger; Stoffers, Peter (2006). "Osbourn Trough: Structure, geochemistry and implications of a mid-Cretaceous paleospreading ridge in the South Pacific". Earth and Planetary Science Letters. 245 (3–4): 685–701. doi:10.1016/j.epsl.2006.03.018. ISSN 0012-821X.
- ^ Barrett et al. 2018, section:Introduction
- ^ Larson et al. 2002, p3
- ^ Vanderkluysen et al. 2014
- ^ Davy, B. (2001). "Basement Structure and Boundaries of the Hikurangi Plateau". Retrieved 2023-05-28.
- ^ Mortimer et al. 2019, p11
- ^ Mortimer et al. 2006, p186
- ^ Barrett et al. 2018, pages 1199-1216
- ^ Beier, Christoph; Van der kluysen, Loÿc; Regelous, Marcel (2011). "Lithospheric control on geochemical composition along the Louisville Seamount Chain". Geochemistry, Geophysics, Geosystems. 12 (9). doi:10.1029/2011GC003690.
- ^ Vanderkluysen et al. 2014, section:Lithospheric Thickness at the Time of Volcanism
- ^ Larson et al. 2002, abstract
- ^ Mortimer et al. 2019, p3
- ^ Barrett et al. 2018, section:Tectonic Setting
- ^ Mortimer et al. 2006, p185-188
- ^ Barrett et al. 2018, Conclusions
Sources
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- Mortimer, N.; Hoernle, K.; Hauff, F.; Palin, J. M.; Dunlap, W. J.; Werner, R.; Faure, K. (2006). "New constraints on the age and evolution of the Wishbone Ridge, southwest Pacific Cretaceous microplates, and Zealandia - West Antarctica breakup" (PDF). Geology. 34 (3): 185–188. doi:10.1130/G22168.1.