Stokes Magnetic Anomaly

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The Stokes Magnetic Anomaly (also known as the Stokes Magnetic Anomaly System, SMAS, New Zealand Junction Magnetic Anomaly, JMA, great Nelson magnetic disturbance, Junction Anomaly, Campbell Magnetic Anomaly System, CMAS) [1] is a magnetic anomaly on the Earth's surface that extends from New Caledonia to the Chatham Rise with complexity consistent with the theory of plate tectonics. [2] [3]

Contents

History

White outline of Zealandia with Stokes Magnetic Anomaly shown as "Z" shape of red (field deviation more than 100nT) and blue (field deviation less than -100nT) magnetic anomaly. The "Z" commences on the Lord Howe Rise and intersects present New Zealand land mass in the Northland Peninsula and bends to extend down the west coast of the country as a 1000km discontinuity until in Fiordland it bends to the east and exits New Zealand's east coast in South Otago. It is defined as far as the Campbell Plateau. Outside the confines of Zealandia on the oceanic plates, the effects of sea flow spreading are seen to the south in terms of parallel magnetic anomaly. Zealandia topography and magnetism.jpg
White outline of Zealandia with Stokes Magnetic Anomaly shown as "Z" shape of red (field deviation more than 100nT) and blue (field deviation less than -100nT) magnetic anomaly. The "Z" commences on the Lord Howe Rise and intersects present New Zealand land mass in the Northland Peninsula and bends to extend down the west coast of the country as a 1000km discontinuity until in Fiordland it bends to the east and exits New Zealand's east coast in South Otago. It is defined as far as the Campbell Plateau. Outside the confines of Zealandia on the oceanic plates, the effects of sea flow spreading are seen to the south in terms of parallel magnetic anomaly.

It is named after Captain (later Admiral) John Lort Stokes by G. C. Farr in 1916 [4] as he described it first although such naming has proved controversial, hence many of the alternative names. [1] [5] [6] The magnetic declinations were observed by Captain Stokes when captaining HMS Acheron and Commander (later Admiral) Byron Drury in HMS Pandora between 1851 and 1853. [1]

Geology

The Stokes Magnetic Anomaly has been characterised for over 3,000 km (1,900 mi) and was essential for understanding the geology of Zealandia as a mainly underwater continent. It extends from 700 km (430 mi) south of New Caledonia to almost the eastern edge of the Campbell Plateau. [5] Over much of its length it has peaks about 30 km (19 mi) to 50 km (31 mi) apart, [5] although this is not the case for much of its New Zealand west coast course. [6] Where the anomaly crosses New Zealand it is displaced by approximately right angle changes in direction for a total of 1,000 km (620 mi) running down the western side of New Zealand from the Northland Peninsula in the North Island to Fiordland but then exiting New Zealand's South Island on its Otago east coast. [6]

The Stokes Magnetic Anomaly has been related to magnetic anomaly extending in Australia as the east Lachlan Fold Belt or New England Fold Belt as an extension of where it commences near the western Challenger Plateau and Lord Howe Rise. This gives an age of up to 83 million years before present in its formation but alternatively, it may be extended to represent the earliest ocean crust formed between New Zealand and Marie Byrd Land in Antarctica so could be even older. [2]

Related Research Articles

<span class="mw-page-title-main">Lord Howe Rise</span> Deep sea plateau from south west of New Caledonia to the Challenger Plateau, west of New Zealand


The Lord Howe Rise is a deep sea plateau which extends from south west of New Caledonia to the Challenger Plateau, west of New Zealand in the south west of the Pacific Ocean. To its west is the Tasman Basin and to the east is the New Caledonia Basin. Lord Howe Rise has a total area of about 1,500,000 km2 (580,000 sq mi), and generally lies about 750 to 1,200 metres under water. It is part of Zealandia, a much larger continent that is now mostly submerged, and so is composed of continental crust. Some have included the 3,500 m (11,500 ft) deep New Caledonia Basin as within the rise, given its continental crust origin, and this would give a larger total area of 1,950,000 km2 (750,000 sq mi).

<span class="mw-page-title-main">Campbell Plateau</span> Large oceanic plateau south of New Zealand and the Chatham Rise

The Campbell Plateau is a large oceanic plateau south of New Zealand and the Chatham Rise. It originated in the Gondwanan breakup and is part of Zealandia, a largely submerged continent. The above sea level parts of the plateau — the Bounty Islands, Antipodes Islands, Auckland Islands and Campbell Island — form part of the New Zealand Subantarctic Islands which were declared a World Heritage Site in 1998. Large parts of the Campbell Plateau lie less than 1000 m below sea level. It rises to 500 m at the Pukaki Rise and emerges above sea level at the Auckland and Campbell Islands.

<span class="mw-page-title-main">Haast Schist</span> Metamorphic unit in New Zealand

The Haast Schist, which contains both the Alpine and Otago Schist, is a metamorphic unit in the South Island of New Zealand. It extends from Central Otago, along the eastern side of the Alpine Fault to Cook Strait. There are also isolated outcrops of the Haast Schist within the central North Island. The schists were named after Haast Pass on the West Coast. The Haast Schist can be divided geographically from north to south into the Kaimanawa, Terawhiti, Marlborough, Alpine, Otago and Chatham schist.

<span class="mw-page-title-main">Volcanism of New Zealand</span> Volcanic activity of New Zealand

The volcanism of New Zealand has been responsible for many of the country's geographical features, especially in the North Island and the country's outlying islands.

<span class="mw-page-title-main">Zealandia</span> Mostly submerged continental crust area in Oceania

Zealandia, also known as Te Riu-a-Māui (Māori) or Tasmantis, is an almost entirely submerged mass of continental crust in Oceania that subsided after breaking away from Gondwana 83–79 million years ago. It has been described variously as a submerged continent, continental fragment, and microcontinent. The name and concept for Zealandia was proposed by Bruce Luyendyk in 1995, and satellite imagery shows it to be almost the size of Australia. A 2021 study suggests Zealandia is over a billion years old, about twice as old as geologists previously thought.

<span class="mw-page-title-main">Bollons Seamount</span> Continental fragment seamount southeast of New Zealand

Bollons Seamount or Bollons Tablemount is a seamount just east of the international date line, a few hundred miles off the coast of New Zealand. It represents a continental fragment that separated from Zealandia as a result of rifting. The seamount was involved in a 2002 survey and collection project defined to find the edge of New Zealand's continental shelf. The Bollons Seamount has been shown to be a site of extensive Cretaceous-era rifting in the area towards the southern Chatham Rise between 83.7 and 78.5 MYA.

<span class="mw-page-title-main">Dunedin Volcano</span> Extinct volcano in New Zealand

The Dunedin Volcano is an extensively eroded multi-vent shield volcano that was active between 16 and 10 million years ago. It originally extended from the modern city of Dunedin, New Zealand to Aramoana about 25 km away. Extensive erosion has occurred over the last 10 million years and Otago Harbour now fills the oldest parts of the volcano. The remnants of the volcano form the hills around Otago Harbour.

<span class="mw-page-title-main">Stratigraphy of New Zealand</span>

This is a list of the units into which the rock succession of New Zealand is formally divided. As new geological relationships have been discovered new names have been proposed and others are made obsolete. Not all these changes have been universally adopted. This table is based on the 2014 New Zealand Stratigraphic Lexicon (Litho2014). However, obsolete names that are still in use and names postdating the lexicon are included if it aids in understanding.

<span class="mw-page-title-main">Geology of the West Coast Region</span> Overview of the geology of the West Coast region

The geology of the West Coast of New Zealand's South Island is divided in two by the Alpine Fault, which runs through the Region in a North-East direction. To the West of the fault Paleozoic basement rocks are interluded by plutones and both are unconformably covered in a sedimentary sequence. To the East of the Alpine Fault are the Mesozoic Alpine Schist and Greywacke of the Southern Alps. There are numerous active faults throughout the region.

<span class="mw-page-title-main">Geology of New Caledonia</span>

The geology of New Caledonia includes all major rock types, which here range in age from ~290 million years old (Ma) to recent. Their formation is driven by alternate plate collisions and rifting. The mantle-derived Eocene Peridotite Nappe is the most significant and widespread unit. The igneous unit consists of ore-rich ultramafic rocks thrust onto the main island. Mining of valuable metals from this unit has been an economical pillar of New Caledonia for more than a century.

<span class="mw-page-title-main">Wairoa North Fault</span> Active fault in New Zealand

The Wairoa North Fault has a maximum Mw6.7 potential for normal fault rupture and is the closest known active fault to the city of Auckland being 40 km (25 mi) to the south east.

<span class="mw-page-title-main">South Auckland volcanic field</span> Extinct volcanic field in New Zealand

The South Auckland volcanic field, also known as the Franklin Volcanic Field, is an area of extinct monogenetic volcanoes around Pukekohe, the Franklin area and north-western Waikato, south of the Auckland volcanic field. The field contains at least 82 volcanoes, which erupted between 550,000 and 1,600,000 years ago.

The Auckland regional geologic faults have low seismic activity, compared to much of New Zealand, but do result in an earthquake risk to the Auckland metropolitan area, New Zealand's largest city. There is also evidence of past tectonic, volcanic associations in a city located within what is, at best, a very recently dormant Auckland volcanic field.

<span class="mw-page-title-main">Ngatutura volcanic field</span> Extinct volcanic field in Waikato district, New Zealand

The extinct Ngatutura volcanic field that was active between 1.54 and 1.83 million years ago is one of four volcanic fields in an intraplate back arc relationship with the still active Hauraki Rift and the presently dormant Auckland volcanic field. The other volcanic fields, which are part of the Auckland Volcanic Province, are the oldest, Okete to the south near Raglan in late Pliocene times. and to the north the younger South Auckland volcanic field.

The Alexandra Volcanic Group is a chain of extinct calc-alkalic basaltic stratovolcanoes that were most active between 2.74 and 1.60 million years ago but is now known to have had more recent activity between 1.6 and 0.9 million years ago. They extend inland from Mount Karioi near Raglan with Mount Pirongia being the largest, with Pukehoua on the eastern slopes of Pirongia, Kakepuku, Te Kawa, and Tokanui completing the definitive lineament. The associated, but usually separated geologically basaltic monogenetic Okete volcanic field, lies mainly between Karioi and Pirongia but extends to the east and is quite scattered.

The Tauranga Volcanic Centre is a geologic region in New Zealand's Bay of Plenty. It extends from the southern end of Waihi Beach and from the old volcanoes of the Coromandel Peninsula that make up the northern part of the Kaimai Range, towards the Taupō Volcanic Zone.

The volcanic activity in the South Island of New Zealand terminated 5 million years ago as the more northern parts of the North Island became extremely volcanically active. The South Islands surface geology reflects the uplift of the Pacific Plate as it collides with the Indo-Australian Plate along the Alpine Fault over the last 12 million years and the termination of subduction, about 100 to 105 million years ago. There is a very small chance of reactivation of volcanism in the Dunedin Volcano. This chance is made slightly higher by the observation that Southland's Solander Islands / Hautere just off the coast of the South Island were active as recently as 50,000 years old, and on a larger scale 150,000 years old.

The Dunedin volcanic group is a volcanic group that covers over 7,800 km2 (3,000 sq mi) of Otago in the South Island of New Zealand. It is a recent reclassification of the group previously known as the Waiareka-Deborah volcanic field due to common magma melt ancestries of the Dunedin Volcano with the overlapping alkali basaltic monogenetic volcanic field. Excluded from the group are a group of volcanics of different composition and older age near Oamaru, which have been given the name previously used for the Dunedin group. The older Waiareka-Deborah volcanic field overlaps the new Dunedin volcanic group geographically; though Dunedin Volcano has been well studied from the 1880s since New Zealand's first school of geology was established at the University of Otago, detailed studies of north-central volcanoes such as the Crater near Middlemarch were done much later, and high-quality composition studies still need to be done to properly classify many volcanics near Oamaru.

<span class="mw-page-title-main">Gifford Guyot</span> Seamount east of Australia

The Lord Howe Seamount Chain of which Gifford Guyot is an eruptive centre, and part of a pair of coral-capped guyots, formed during the Miocene. The Gifford Marine Park is co-located off the Queensland coast near Brisbane.

Nick Mortimer is a New Zealand geologist, who has made a name for himself with his work on Zealandia.

References

  1. 1 2 3 Hatherton, Trevor (1975). "Letters to the editor: Stokes magnetic anomaly—magnetic system or magnetic supergroup?". New Zealand Journal of Geology and Geophysics. 18 (3): 519–521. Bibcode:1975NZJGG..18..519H. doi: 10.1080/00288306.1975.10421554 .
  2. 1 2 Sutherland, Rupert (1999). "Basement geology and tectonic development of the greater New Zealand region: an interpretation from regional magnetic data". Tectonophysics. 308 (3): 341–362. Bibcode:1999Tectp.308..341S. doi:10.1016/S0040-1951(99)00108-0. ISSN   0040-1951.
  3. Kenny, JA; Lindsay, JM; Howe, TM (2012). "Post-Miocene faults in Auckland: insights from borehole and topographic analysis". New Zealand Journal of Geology and Geophysics. 55 (4): 323–343. Bibcode:2012NZJGG..55..323K. doi:10.1080/00288306.2012.706618. S2CID   128945408.
  4. Hatherton, Trevor; Sinson, R. H. (1970). "Junction Magnetic Anomaly North of Waikato River". New Zealand Journal of Geology and Geophysics. 13 (3): 655–662. Bibcode:1970NZJGG..13..655H. doi: 10.1080/00288306.1970.10431336 .
  5. 1 2 3 Wellman, H. (1973). "The Stokes Magnetic Anomaly". Geological Magazine. 110 (5): 419–429. Bibcode:1973GeoM..110..419W. doi:10.1017/S0016756800036207. S2CID   131561689.
  6. 1 2 3 Hunt, Trevor (1978). "Stokes magnetic anomaly system". New Zealand Journal of Geology and Geophysics. 21 (5): 595–606. Bibcode:1978NZJGG..21..595H. doi:10.1080/00288306.1978.10424087.