Macauley Island
Geography | |
---|---|
Location | South Pacific Ocean |
Coordinates | 30°14′S 178°26′W / 30.233°S 178.433°W |
Archipelago | Kermadec Islands |
Area | 3.06 km2 (1.18 sq mi) |
Length | 2.5 km (1.55 mi) |
Width | 1.8 km (1.12 mi) |
Highest elevation | 238 m (781 ft) |
Highest point | Mount Haszard |
Administration | |
New Zealand | |
Demographics | |
Population | 0 |
Additional information | |
Nature Reserve |
Macauley Island is a volcanic island in New Zealand's Kermadec Islands, approximately halfway between New Zealand's North Island and Tonga in the southwest Pacific Ocean. It is part of a larger submarine volcano that features a 10.5 by 7 kilometres (6.5 mi × 4.3 mi) wide underwater caldera northwest of Macauley Island. Two islets, Haszard Island and Newcome Rock, lie east offshore of Macauley Island. The island is mostly surrounded by high cliffs that make accessing it difficult; the inland parts are mostly gently sloping terrain covered with ferns and grasses.
The island was formed during several volcanic episodes that produced mainly basaltic rocks as lava flows. During the Holocene, a large explosive eruption produced the Sandy Bay Tephra; this eruption may have had a volume of more than 100 cubic kilometres (24 cu mi) and the Macauley caldera might have formed during that occasion. Later, the Haszard Formation built most of the current surface of Macauley Island. Two uncertain eruptions took place during the 19th century offshore Macauley Island; a hydrothermal vent system is active on Macauley Cone in the caldera.
Macauley Island is an important breeding place for numerous seabirds, which come on land only to reproduce. While the island is uninhabited, Polynesians, and during the 19th century whalers, introduced goats, pigs and rats which damaged the island's ecosystem. During the 20th and 21st century these invasive species were largely eradicated, leading to a recovery of the previous vegetation. The island is part of a protected area.
Geography and geomorphology
[edit]Macauley Island is in the Kermadec Islands, 109 kilometres (68 mi) south-southwest of Raoul Island[1] and roughly halfway between Tonga and New Zealand.[2] Cheeseman Island and Curtis Island lie south-southwest of Macauley Island, and Havre and L'Esperance Rock are even farther south;[3] together these islands form the southern group of the Kermadec Islands,[4] of which Macauley Island is the largest.[4] Under good conditions Raoul Island can be seen from Macauley Island.[5] Located within the exclusive economic zone of New Zealand,[6] the islands are since 1990 within the Kermadec Islands Marine Reserve[7] and the Kermadec Benthic Protected Area[6] administered by the New Zealand Department of Conservation.[8] The islands are, with the exception of the weather station on Raoul Island, uninhabited.[9]
The volcano rises from a depth of 1,700 metres (5,600 ft) where it is 23–30 kilometres (14–19 mi) wide;[10] it is elongated in east-southeast direction[11] and features a 10.5 by 7 kilometres (6.5 mi × 4.3 mi) wide submarine caldera northwest of Macauley Island. The caldera floor lies at 1,100 metres (3,600 ft) depth and its rim at 600 metres (2,000 ft).[12] The caldera is elongated in east-northeast direction[3] and features north-northeast trending lineaments that extend to Macauley Island. Jumbled blocks, presumably from landslides or slumps, cover the portions of the caldera adjacent to Macauley Island,[11] and there is evidence of collapses on the western caldera margin.[13] A fault runs inside the caldera next to its southeastern margin.[14] The caldera floor is covered with pumice,[14] and thick pumice deposits occur on the flanks of Macauley volcano.[15]
North-northwest of the caldera is a 9 kilometres (5.6 mi) long structure called Lloyd dome[16] or Curtis Ridge;[17] it is surmounted by a lineament of cones that rise to 80 metres (260 ft) below sea level.[16] 300 metres (980 ft) high and 700 metres (2,300 ft) wide[13] Macauley Cone is located on the southeastern caldera margin and rises to 250 metres (820 ft) depth.[12] It is capped by a 80 metres (260 ft) wide and 45 metres (148 ft) deep crater[18] with a floor covered with ash and sulfur, while its slopes are covered with talus.[19] Parasitic vents and structures have been identified on the caldera rim[13] and submarine slopes of Macauley Island volcano during bathymetric analysis,[20] some are the source of lava flows[12] that extend into the caldera and down the flanks.[13]
The seafloor on the slopes of Macauley volcano is covered with sand, rock, breccia and bacterial mats.[21] "Sediment waves" up to 1 kilometre (0.62 mi) long and 100 metres (330 ft) wide occur on the submarine slopes[22] and extend over 55 kilometres (34 mi) away from the volcano.[23] These waves appear to have formed in part during sector collapses and in part during density flows triggered by eruptions;[24] the size of the latter waves may be indicative of the large size of eruptions.[25] The submarine slopes are dissected by canyons and channels.[16] The total volume of the volcano is about 269 cubic kilometres (65 cu mi),[10] of which less than five percent are emergent.[14]
Macauley Island
[edit]Parts of the volcano emerge above sea level, forming Macauley Island, Haszard Island and Newcombe Rock. Together they have an area of about 3 square kilometres (1.2 sq mi), making it the second-largest island in the Kermadec Islands.[26] Macauley Island was also known as Green Island.[27]
Macauley Island is about 2.1 kilometres (1.3 mi) wide with a roughly circular[1] to rectangular shape[28] and rises from an average elevation of about 100 metres (330 ft) to the 238 metres (781 ft) high Mount Haszard in the northern part of the island.[26] Seen from the north the island has the shape of a wedge, while it has a more rounded shape when seen from the east.[29]
The island has a surface area of 3.06 square kilometres (306 ha).[30] Most of the island is a gently tilted plateau, cut by gullies and ravines which are the only way to reach the inside of the island.[31] The deepest of these gullies is 45 metres (148 ft) deep Grand Canyon on the eastern side of Macauley Island;[30] there is evidence that the gullies have become deeper in historical times. Flowing water only occurs after rainfall.[32] The island is geologically unstable, with beaches and landforms frequently shifting due to erosion[33] during rainfall and tropical cyclones, but also due to earthquakes.[5] A castaway depot was established on the northeastern side of[32] Macauley Island in 1888.[34]
Cliffs with heights of over 61 metres (200 ft) surround most of Macauley Island[1] and allow landing only at Sandy Bay,[35] a 140 metres (150 yd) long beach.[28] Boulder, gravel and sand beaches occur at some places, while others have steep rocky slopes at subtidal depths with crevices, caves and overhangs.[36] At its northwestern end[37] west of Mount Haszard, the steep Perpendicular Cliff drops into the southern part of the caldera. The structure of the shield volcano with lava flows, tephra and two volcanic craters crop out in the cliff.[26] South and southwest of Mount Haszard are two more craters[37] known as Haszard Crater and Macauley Crater.[4]
Haszard Island lies 0.23 kilometres (250 yd)[1] east of Macauley Island, next to Sandy Bay.[37] Its name is derived from Henry Douglas Morpeth Haszard (at first, it was named Roaches' Isle),[38] and, like that of Mount Haszard, is often spelled as Hazard.[39] It has a surface of about 0.032 square kilometres (8 acres)[1] and is entirely surrounded by cliffs, making access difficult.[40] Newcombe Rock - also known as Haszardette - is located northeast of Haszard Island and may be part of the same edifice, separate from the Macauley Island one.[41][4] Three more emergent rocks are found northeast and southwest of Haszard Island and south of Macauley Island,[32] and a shallow rock named Mac Donald lies reportedly a few kilometres off Mount Haszard.[42]
Geology
[edit]In the Southwest Pacific, the Pacific Plate subducts beneath the Australian Plate[43] and a set of microplates[44] in the 2,550 kilometres (1,580 mi) long[45] and maximally 10,800 metres (35,400 ft) deep[46] Kermadec Trench.[47] This subduction has given rise to the Tonga-Kermadec volcanic arc,[43] which is subdivided at 25.6° latitude (where the Louisville seamount chain subducts in the trench) in the northern Tonga and the southern Kermadec arc.[45] In the Kermadec arc, subduction proceeds at a rate of 50–70 millimetres per year (2.0–2.8 in/year).[48]
The Kermadec arc consists mainly of 33[48] submarine volcanoes and calderas[43] and extends from White Island next to New Zealand to Raoul Island; most of these volcanoes however are submarine.[49] The volcanoes are formed principally by basaltic and andesitic magmas[43] and are lined up in a 40 kilometres (25 mi) wide zone west of the trench.[50] The volcanoes are located 15–25 kilometres (9.3–15.5 mi) west of the ridge,[12] except for Macauley, Raoul and Curtis Islands which are on it,[48] and rise on an oceanic crust of Eocene age.[51] Volcanism began in the Pliocene and has occurred at the present-day location of the Tonga-Kermadec Ridge for about one million years.[47] Many of the volcanoes were discovered using bathymetry,[52] and about 80% show hydrothermal activity.[18] Because of its mostly submarine location, volcanism in the Kermadec arc is poorly understood.[53]
The Kermadec Islands are the emergent part of the Kermadec arc,[26] and most of the ridge lies at over 500 metres (1,600 ft) depth.[2] The islands are usually found on ridges perpendicular to the main ridge, implying that local lineaments control the position of volcanoes;[26] they are separated from each other by water depths of over 900 metres (3,000 ft).[2] twenty-four kilometres (15 mi) [12] west-northwest of Macauley Island lies Giggenbach, a submarine volcano, and even farther west ares the Havre Trough[47] and a caldera.[54] This trough separates the Kermadec microplate from the Australian plate[44] and it and the Lau Basin began to form through crustal spreading 6 million years ago; the lineaments of the Macauley caldera appear to match these of the Havre Trough.[55] The Kermadec-Havre system is considered to be an archetype of a backarc-volcanic arc system.[53]
Composition
[edit]Most of the rocks on Macauley Island have a basaltic composition,[26] which define an alumina-rich to tholeiitic suite[56] with intermediate potassium contents.[57] The rocks contain olivine and pyroxene phenocrysts with rare glass,[58] and the Sandy Bay Tephra contains augite, hypersthene, ilmenite, magnetite and plagioclase.[59] There is a single instance of dacite[3] and rhyolite in Sandy Bay Tephra,[60] and evidence for earlier felsic eruptions;[52] with the exception of that Macauley Island rocks have a largely uniform composition.[61][60] Magma mingling processes appear to have occurred prior to the eruption of the Sandy Bay Tephra.[62]
Gabbro and basalts with different compositions occur as xenoliths[60] and resemble Raoul Island rocks.[63] Chemical alteration has given rise to gypsum, hematite, kaolinite, montmorillonite, natroalunite and tridymite. The altered rocks have pink and red colours[37] and there are occurrences of palagonite.[64] Hyaloclastite is found in the sea at shallow depths[65] and ferromanganese crusts have been dredged from the submarine flanks of Macauley Island.[66]
The volcano is believed to consist mostly of basaltic rocks.[67] The occurrence of felsic rocks at Macauley Island[45] and elsewhere in the Tonga-Kermadec volcanic arc is unexpected.[68] Processes where magma ascending into the lower crust heats it until it melts (anatexis) and dehydrates have been invoked to explain the felsic volcanism in the Kermadec arc.[55] In contrast, an origin through fractional crystallization of basaltic magmas is unlikely for a number of reasons.[69][70] The backarc extension in the Havre Trough, where tectonic lineaments match the trend of the Macauley caldera and of Denham Caldera on Raoul Island, may also have influenced the explosive activity at both calderas.[71]
Climate and oceanic conditions
[edit]The climate of Macauley Island is expected to resemble that of Raoul Island, where temperatures range between 12–25 °C (54–77 °F) and about 1,500 millimetres (60 in) of precipitation fall each year. In summer, winds blow from east and southeast and the rest of the year from northwest. Mean sunshine duration per year is about 2100 hours.[32]
The Kermadec Islands are largely exposed to oceanic swells coming from all directions.[6] Ocean current regimes in this area of the Pacific Ocean are poorly known and appear to be seasonal, with northerly currents during summer and southeasterly ones the rest of the year.[72] Sea surface temperatures at Raoul Island to the north range between 16–26 °C (61–79 °F) and these at L'Esperance Rock south between 14–26 °C (57–79 °F),[73] thus they are considered too cold to be tropical.[46] Waters are salty and clear.[72]
Ecosystem
[edit]Most of the island is covered by beadfern and sedgeland,[74] trees are rare.[75] Several vegetation associations occur, such as turf along the coasts, lichens and mosses on the northwestern cliffs, sedgelands mostly at the periphery of the island, shrubs at various sites[76] and dwarf ngaio[77] and Homalanthus forests.[78] Moisture-loving plants occur in the canyons and gullies.[79] 68 plant species were recorded on Macauley Island in 2008,[31] and there are bryophytes, lichens, lycophytes, pteridophytes, seaweeds and spermatophytes. One fungus was recorded in 2015, the artist's conk.[80] There have been historical changes in vegetation due to the introduction and eradication of pigs and goats and a spread of ferns that may be due to climatic changes.[81]
Macauley Island has the largest seabird population of New Zealand.[82] Seabirds live on the sea and come to land only to breed;[83] birds found breeding on Macauley Island include black noddies, black-winged petrels, grey noddies, Kermadec parakeets, Kermadec petrels, little shearwaters, masked boobies, red-tailed tropicbirds, sooty terns, wedge-tailed shearwaters, white-bellied storm petrels and white-naped petrels.[84] Of these, the Kermadec parakeet is the only land bird on Macauley Island.[85] Catastrophic volcanic eruptions that periodically wipe the animals out may be the reason why Macauley Island and other Kermadec islands lack endemic birds.[86] In 1988, 5.2 million breeding birds were reported.[27] They nest mainly in the sedgelands[87] and cliffs,[88] and both Macauley[5] and Haszard Island are heavily burrowed by nesting seabirds.[89] Birds may fly from the colonies on Macauley Island to islands farther west, such as Balls Pyramid and Lord Howe Island.[90]
Invertebrates reported from the islands include ants, beetles, butterflies, centipedes, crickets, flies, moths, orthopterans, snails and spiders[91] although centipedes were not recorded in 2011 and millipedes and earthworms were absent as well.[92]
Marine organisms
[edit]Unlike the land-based fauna,[8] the marine flora and fauna of the Kermadec Islands is mostly tropical and subtropical. It resembles that of Lord Howe Island more than that of New Zealand[2] and there are reef-building corals.[93] Reefs have been reported from boulders and rocks[72] at depths of over 7 metres (23 ft).[94] These reefs are dominated by algae with proper corals covering less than one percent of the ground;[95] there are no proper coral reefs at Macauley Island[93] presumably owing to the only marginally suitable water temperatures, as has been observed at other subtropical sites.[96] Spiny kelp occur at Macauley Island, the northernmost occurrence of this species.[97]
Squids,[7] sharks, dolphins[98][99] and crown-of-thorns starfish occur at Macauley Island.[100] Other animal taxa include ascidians, bivalves, bony fish, cartilaginous fish, crabs,[101] crinoids,[98] echinoids, eels, gastropods, hermit crabs, hydrozoans, nudibranchs, ophiuroids, polychelida, porifers, sea anemones, sea pens, sea stars, soft corals, stony corals, tube worms and tunicates.[101] Animal density is higher in the areas of hydrothermal venting.[102] About 105 mollusc taxa[103] and numerous bryozoan species have been identified in the surrounding sea.[104] Species discovered at Macauley Island and other Kermadec volcanoes are the crabs Gandalfus puia (Macauley Island and submarine volcanoes farther south)[105] and Xenograpsus ngatama (Macauley Island and Brothers volcano),[106] the crustacean Munidopsis maunga (Macauley caldera),[107] and the mussel Vulcanidas isolatus (at Macauley Island and Giggenbach volcano).[108]
Human activity and ecological impacts
[edit]The Polynesian rat was presumably introduced by Polynesians, while goats and pigs were introduced presumably by whalers in the 19th century[109] probably as an emergency food supply for shipwrecked sailors;[110] whalers also burned the shrubs of the island.[111] The island was reported in 1789 to be heavily populated by rats and mice.[38] While not as severe as at Raoul Island,[112] these introduced animals altered the ecosystem of the island,[109] preying on birds and confining many plant species to inaccessible cliffs;[38] they might be responsible for the absence of several birds known from Raoul Island on Macauley Island[113] and for changes in the vegetation of Macauley Island between human visits during the 20th century.[114] Additionally, plants may have been imported by later visitors[115] or birds[116] and flotsam/marine debris arriving from New Zealand is frequently reported.[72]
In the late 20th century, there have been efforts to eradicate introduced species from the Kermadec Islands.[117] Pigs had died out by 1910 and goats were removed in the 1960s[109] by the New Zealand Wildlife Service;[114] about 3,200 goats were killed during that occasion.[118] After an initial delay due to concerns that toxic baits used for rat removal could impact parakeet populations,[119] in 2006 the New Zealand Department of Conservation began an effort to eradicate the Polynesian rat.[109] This eradication programme was probably successful, leading to the recovery of a more diverse fern-sedge vegetation that may be still underway as of 2015[update][78] and could lead to a future reduction of fern occurrences.[120] Rats and other rodents have never been reported from Haszard Island.[38] Since the establishment of the Kermadec Islands Marine Reserve, certain activities such as discharging wastewaters, fishing, mining and laying submarine cables are prohibited around Macauley Island.[7]
Eruption history
[edit]The history of Macauley Island is easily[121] recognizable from the cliffs on its northern side,[3] where five geological formations crop out; from bottom to top these are the North Cliff Lavas, the Boulder Beach Formation, the Annexation Lavas, the Sandy Bay Tephra and the Haszard Formation.[122] An additional formation, the Grand Canyon Formation, crops out in the east of the island.[37] Tephra layers dating to 130,000, over 40,000, 30,000, 8,400 and 5,600 years ago identified in marine cores around Macauley Island may originate from eruptions there.[16][123][124]
Rocks dip away from the northwestern side of the island[41] and all the rocks appear to have been emplaced above sea level;[125] there is no evidence for orogenic deformation although the presence of subaqueous lava flows indicates that recent eruptions occurred during a time of low sea level.[63] During the sea level lowstand of the last glacial period, a much larger area of the island was exposed above sea level.[16]
Pumices dredged from Macauley Island bear evidence of having formed through a unique process ("Tangaroan eruption"), where expanding magma forms a foam-like structure that fragments into numerous spherical pieces. These pieces upon contacting water solidify on the outside but remain molten on the inside. These pumice deposits are distinct from the Sandy Bay Tephra deposits and probably formed during additional eruptions.[126] The chemistry and density of Macauley Island pumices indicate a complex volcanic history.[127]
Pre-Sandy Bay activity
[edit]The lava flows of the North Cliff Lavas are the oldest formation that crops out,[3] and are part of a shield volcano[128] with at least one crater.[37] Little erosion took place before phreatomagmatic eruptions emplaced the tephras and lavas of the Boulder Beach Formation,[64] presumably after water had entered the vent.[129] Dykes, most of which are correlated to the Annexation Lavas, are intruded into the Boulder Beach Formation.[64]
The Annexation Lavas are widespread on Macauley Island and also occur at Haszard Island and Newcombe Rock. Hawaii-like eruptions of vents located northwest of present-day Macauley Island produced lava flows with average thicknesses of 1 metre (3 ft 3 in) or less intercalated with brown tephra. Dykes fed lava to additional vents, including the Newcombe Rock volcanic plug. Lava also ponded in a crater that crops out in Perpendicular Cliffs; the ponded lava which was originally interpreted as a volcanic intrusion. The total volume of the Annexation Lavas is about 1 cubic kilometre (0.24 cu mi), they reach total thicknesses of about 115 metres (377 ft). Along with volcanic activity, tectonic activity increased during the Annexation Lavas stage, giving rise to normal faulting and subsidence; at the end of the stage a summit crater was left.[130] At this time, Macauley Island may have had a diameter of 4 metres (13 ft) and maximum elevation of 150 metres (490 ft).[61]
Sandy Bay eruption
[edit]The Sandy Bay Tephra was erupted 7,200[47] or 6,310 years ago[39] during the formation of the Macauley caldera[3] from a shallow submarine[131] vent close to Macauley Island,[132] and is named after Sandy Bay.[133] Its total volume is poorly known,[15] an estimate of 100 cubic kilometres (24 cu mi) inferred from the caldera volume would make the eruption that gave rise to Sandy Bay Tephra one of the largest volcanic eruptions during the Holocene[134] but it is possible that the Macauley caldera formed during multiple eruptions.[135] A submarine eruption jet breached the sea surface,[136] producing at least thirty successive pyroclastic flows, pyroclastic surges and tephra fallout episodes on Macauley Island. The eruption products buried and sometimes eroded earlier deposits. The flows were cold, most likely from interaction with seawater. The flows buried the scrubby vegetation on Macauley Island, leaving wood casts in the rocks.[137]
The Sandy Bay Tephra has a conspicuous white colour, contrasting with the dark colours of the rest of Macauley Island. It consists of dacitic tephra,[130] which forms layered deposits containing lapilli, pumice, sand and fine volcanic ash. The total thickness of the Sandy Bay Tephra ranges from about 100 metres (330 ft) in the south to 15 metres (49 ft) in the north,[132] with evidence of thicker deposits in topographic depressions.[137] Basaltic and plutonic rocks are found embedded in the Sandy Bay rocks[130] and reach sizes of 1.5 metres (4 ft 11 in);[132] they indicate that older rocks were integrated into the erupting magma.[59] The total volume of Sandy Bay Tephra on Macauley Island is about 0.1–0.2 cubic kilometres (0.024–0.048 cu mi) but it is likely that the total volume of the tephra was considerably larger.[134] Erosion has affected the Sandy Bay Tephra,[138] leaving cliffs around Haszard Islet.[133]
Tephra from the Sandy Bay eruption has been identified in sediment cores taken around the island[139] and formed concentric ridges on the western flank of submarine Macauley.[13] It is likely that the eruption produced large amounts of pumice, which would have been transported by ocean currents to other islands in the Southwest Pacific.[134] Caldera collapse and collapses of caldera flanks perhaps produced tsunamis which may have hit the Bay of Plenty region of New Zealand.[140] The Sandy Bay Tephra is the only demonstrated felsic eruption at Macauley volcano;[141] the presence of obsidian and pitchstone in the Sandy Bay Tephra indicate that earlier felsic eruptions took place,[121] but their dates are unknown.[142]
Haszard Formation
[edit]The Haszard Formation makes up the bulk of exposed Macauley Island rocks.[37] It includes the Parakeet Tuff, Haszard Scoria and Cascade Lava Members,[64] which probably were produced by the same eruptive episode.[134] The 1 cubic kilometre (0.24 cu mi) Cascade Lava was produced from the craters at Mount Haszard and other vents; the lava flows reach thicknesses of 1–2 metres (3 ft 3 in – 6 ft 7 in) and their eventual course was strongly influenced by topography. The lavas were overlaid by the bedded Haszard Scoria. [143] Submarine phreatomagmatic activity generated the Parakeet Tuff, which was erupted along with the Haszard Scoria and consists of lapilli and volcanic ash.[144] Both the Haszard Scoria[143] and the Parakeet Tuff include rafted blocks with diameters of 2 metres (6 ft 7 in).[144]
The Parakeet Tuff and Haszard Scoria[144] are thought to have originated in the southeastern sector of the caldera, [3] 0.75 kilometres (0.47 mi) northwest of Macauley Island.[11] Their emplacement may have begun decades or centuries after the Sandy Bay Tephra eruption, during which rainfall eroded the Sandy Bay Tephra and formed valleys later filled by the Haszard Formation.[134] The eruption was centred at the crater of the Annexation Lavas and on flank vents and reached sub-Plinian dimensions; the crater eventually collapsed below sea level, perhaps during the slumping of the southeastern flank of Macauley Caldera, but the eruption continued as a Surtseyan eruption. Several small phreatic craters on southern Macauley Island probably relate to the Haszard Formation, as does the Grand Canyon Formation formed in a lake formed through the damming of a valley at the eastern end of the island.[11][145]
Historical eruptions and hydrothermal activity
[edit]Macauley Island is considered to be a dormant volcano.[146] An eruption supposedly took place in 1825 at a "Brimstone Island" 45 kilometres (28 mi) west of Macauley Island, while another was reported 1 December 1887 north-northeast. These locations may be erroneous given the absence of bathymetric structures coinciding with their location, but they may be historical eruptions of the Macauley Island volcano.[61] There are anecdotal reports of earthquakes,[5][40] and a faint smell of sulfur was reported at the northern cliffs, next to the oldest rocks of Macauley Island.[37]
Hydrothermal activity occurs in the submarine Macauley Cone, where white fluids and occasional bubbles emanate from rocks[18] and chimney-shaped vents.[147] Elemental sulfur occurs around the vents,[18] which release warm (112 °C (234 °F)) acidic mineral-rich waters[148] with a brine-like composition[149] and intense hydrothermal plumes.[19] These waters may be derived from magmatic fluids[149] and their helium isotope ratios appear to vary between observations.[150] The influence of the hydrothermal emanations extend 7 kilometres (4.3 mi) from the volcano. One or two additional vent sites are suspected to exist in the Macauley Caldera.[151] There is evidence that a lake of molten sulfur once filled the Macauley Cone crater[152] and left sulfur deposits with thicknesses exceeding 1 metre (3 ft 3 in).[153]
A vent biota has become established around the hydrothermal vents[13] consisting of mussels: Vulcanidas isolatus at shallow depths and Gigantidas gladius at both shallow and intermediate depths.[154] Sea stars prey on them while crabs and tonguefish graze at the sulfurous crater walls.[155] The hydrothermal activity occurs at shallow depths,[156] thus fluids can enter the photic zone where biological productivity is highest.[157]
History
[edit]Macauley Island was first discovered on 30 June 1788 by the Lady Penrhyn,[158] but it is likely that Polynesians visited the island during the last 700 years despite the lack of direct archaeological evidence[109] other than an obsidian flake discovered in 2015.[159] They may have obtained obsidian from the island.[160] The island was originally named Macaulay,[161] after George Mackenzie McCaulay, alderman of the City of London who had contracted the voyage of the Lady Penrhyn.[162]
Macauley Island and other Kermadec islands are part of New Zealand's territory since the 19th century;[163] early explorers envisaged planting trees on Macauley Island and using the Kermadec islands as places to settle from New Zealand,[164] and in 1957 were briefly considered as a potential testing ground for the British nuclear weapons programme.[165] Archaeological excavations were conducted in 1990.[166]
See also
[edit]- New Zealand outlying islands
- List of volcanoes in New Zealand
- List of islands of New Zealand
- List of islands
- Island restoration
- Desert island
References
[edit]- ^ a b c d e Brothers & Martin 1970, p. 330.
- ^ a b c d Francis, Grace & Paulin 1987, p. 1.
- ^ a b c d e f g Lloyd et al. 1996, p. 296.
- ^ a b c d de Lange 2015, p. 208.
- ^ a b c d Furey, Ross-Sheppard & Prickett 2015, p. 513.
- ^ a b c Nelson et al. 2018, p. 534.
- ^ a b c Braid & Bolstad 2019, p. 402.
- ^ a b Veitch et al. 2004, p. 61.
- ^ Song 2018, p. 253.
- ^ a b Wright, Worthington & Gamble 2006, p. 267.
- ^ a b c d Lloyd et al. 1996, p. 306.
- ^ a b c d e Glover 2004, p. 283.
- ^ a b c d e f Wright, Worthington & Gamble 2006, p. 272.
- ^ a b c Wright, Worthington & Gamble 2006, p. 271.
- ^ a b Barker et al. 2012, p. 1428.
- ^ a b c d e Shane & Wright 2011, p. 430.
- ^ Von Cosel & Marshall 2010, p. 62.
- ^ a b c d Kleint et al. 2019, p. 3.
- ^ a b de Ronde et al. 2015, p. 274.
- ^ Shane & Wright 2011, p. 428.
- ^ Beaumont, Rowden & Clark 2012, p. 22.
- ^ McKay et al. 2018, p. 66.
- ^ Casalbore et al. 2020, p. 1406.
- ^ Casalbore et al. 2020, p. 1407.
- ^ Casalbore et al. 2020, p. 1432.
- ^ a b c d e f Lloyd et al. 1996, p. 295.
- ^ a b Gaskin 2011, p. 9.
- ^ a b Williams & Rudge 1969, p. 17.
- ^ Wyville Thomson & Murray 1885, p. 475.
- ^ a b Veitch et al. 2004, p. 63.
- ^ a b de Lange 2015, p. 207.
- ^ a b c d Williams & Rudge 1969, p. 18.
- ^ Greene, Scofield & Dilks 2004, pp. 8–9.
- ^ Doyle, Singleton & Yaldwyn 1979, p. 124.
- ^ Brothers & Martin 1970, p. 331.
- ^ Brook 1999, p. 437.
- ^ a b c d e f g h Lloyd et al. 1996, p. 298.
- ^ a b c d Veitch et al. 2004, p. 64.
- ^ a b Smith, Stewart & Price 2003, p. 174.
- ^ a b Greene, Scofield & Dilks 2004, p. 9.
- ^ a b Brothers & Martin 1970, p. 332.
- ^ Gunn 1888, p. 603.
- ^ a b c d Shane & Wright 2011, p. 422.
- ^ a b Wright, Worthington & Gamble 2006, p. 266.
- ^ a b c Smith et al. 2003, p. 100.
- ^ a b Gaskin 2011, p. 5.
- ^ a b c d Shane & Wright 2011, p. 423.
- ^ a b c Timm et al. 2012, p. 1527.
- ^ Kleint et al. 2019, p. 2.
- ^ Smith et al. 2003, p. 101.
- ^ Timm et al. 2012, p. 1528.
- ^ a b Smith et al. 2003, p. 102.
- ^ a b Wright, Worthington & Gamble 2006, p. 264.
- ^ Gill et al. 2021, p. 15.
- ^ a b Smith et al. 2003, p. 114.
- ^ Brothers & Martin 1970, p. 343.
- ^ Smith et al. 2003, p. 106.
- ^ Brothers & Martin 1970, p. 341.
- ^ a b Smith, Stewart & Price 2003, p. 177.
- ^ a b c Brothers & Martin 1970, p. 342.
- ^ a b c Lloyd et al. 1996, p. 308.
- ^ Shane & Wright 2011, p. 425.
- ^ a b Brothers & Martin 1970, p. 345.
- ^ a b c d Lloyd et al. 1996, p. 299.
- ^ Shane 2017, p. 51.
- ^ Dubinin et al. 2008, p. 1219.
- ^ Smith, Stewart & Price 2003, p. 192.
- ^ Smith et al. 2003, p. 99.
- ^ Smith, Stewart & Price 2003, p. 188.
- ^ Wright, Worthington & Gamble 2006, p. 286.
- ^ Worthington, Gregory & Bondarenko 1999, p. 44.
- ^ a b c d Brook 1999, p. 438.
- ^ Francis, Grace & Paulin 1987, p. 10.
- ^ Barkla et al. 2008, p. 373.
- ^ Greene, Scofield & Dilks 2004, p. 13.
- ^ de Lange 2015, p. 215.
- ^ Barkla et al. 2008, p. 377.
- ^ a b de Lange 2015, p. 222.
- ^ de Lange 2015, p. 216.
- ^ de Lange 2015, p. 211.
- ^ Greene, Scofield & Dilks 2004, p. 21.
- ^ The Kermadecs – Science Symposium Proceedings 2010 2010, p. 47.
- ^ Gaskin 2011, p. 2.
- ^ Veitch et al. 2004, p. 82.
- ^ Veitch et al. 2004, p. 83.
- ^ Holdaway, Worthy & Tennyson 2001, pp. 149–150.
- ^ de Lange 2015, p. 221.
- ^ Gaskin 2011, p. 23.
- ^ Greene, Scofield & Dilks 2004, p. 24.
- ^ Holdaway & Anderson 2001, p. 99.
- ^ Greene, Scofield & Dilks 2004, p. 25.
- ^ Chinn 2015, p. 447.
- ^ a b Francis, Grace & Paulin 1987, p. 11.
- ^ Brook 1999, p. 441.
- ^ Brook 1999, p. 448.
- ^ Brook 1999, p. 452.
- ^ Nelson et al. 2018, p. 536.
- ^ a b Beaumont, Rowden & Clark 2012, p. 24.
- ^ Duffy, Baker & Constantine 2015, p. 506.
- ^ Liggins, Gleeson & Riginos 2014, p. 381.
- ^ a b Beaumont, Rowden & Clark 2012, p. 21.
- ^ Beaumont, Rowden & Clark 2012, p. 23.
- ^ Keable & Reid 2015, p. 249.
- ^ Gordon 2014, pp. 1597–1628.
- ^ Mclay 2007, pp. 5–6.
- ^ Mclay 2007, pp. 15–16.
- ^ Schnabel & Bruce 2006, pp. 58–59.
- ^ Von Cosel & Marshall 2010, p. 59.
- ^ a b c d e de Lange 2015, p. 209.
- ^ Nisbet 1979, p. 264.
- ^ Barkla et al. 2008, p. 376.
- ^ Gaskin 2011, p. 6.
- ^ Veitch et al. 2004, p. 85.
- ^ a b Sykes 1969, p. 13.
- ^ de Lange 2015, p. 213.
- ^ Greene, Scofield & Dilks 2004, p. 23.
- ^ Veitch et al. 2004, p. 84.
- ^ Williams & Rudge 1969, p. 19.
- ^ Greene, Scofield & Dilks 2004, p. 6.
- ^ de Lange 2015, p. 224.
- ^ a b Smith et al. 2003, p. 103.
- ^ Lloyd et al. 1996, p. 297.
- ^ Latter 1985, pp. 57–58.
- ^ Bourne et al. 2023, p. 809.
- ^ Brothers & Martin 1970, p. 333.
- ^ Barker et al. 2012, p. 1439.
- ^ Barker et al. 2012, p. 1441.
- ^ Lloyd et al. 1996, pp. 296, 299.
- ^ Lloyd et al. 1996, p. 307.
- ^ a b c Lloyd et al. 1996, p. 300.
- ^ Rotella et al. 2015, p. 318.
- ^ a b c Lloyd et al. 1996, p. 301.
- ^ a b Brothers & Martin 1970, p. 337.
- ^ a b c d e Lloyd et al. 1996, p. 303.
- ^ Barker et al. 2012, p. 1440.
- ^ Rotella et al. 2015, p. 329.
- ^ a b Lloyd et al. 1996, p. 302.
- ^ Lloyd et al. 1996, pp. 307–308.
- ^ Shane & Wright 2011, p. 431.
- ^ Law 2008, p. 18.
- ^ Casalbore et al. 2020, p. 1402.
- ^ Smith, Stewart & Price 2003, p. 185.
- ^ a b Lloyd et al. 1996, p. 304.
- ^ a b c Lloyd et al. 1996, p. 305.
- ^ Brothers & Martin 1970, p. 340.
- ^ Latter 1985, p. 56.
- ^ Beaumont, Rowden & Clark 2012, p. 50.
- ^ Kleint et al. 2019, p. 8.
- ^ a b Kleint et al. 2019, p. 18.
- ^ Status Conference Research Vessels 2020 2020, p. 310.
- ^ de Ronde et al. 2007, p. 7.
- ^ de Ronde et al. 2015, p. 276.
- ^ de Ronde et al. 2015, p. 284.
- ^ Status Conference Research Vessels 2020 2020, p. 311.
- ^ de Ronde et al. 2015, p. 277.
- ^ Status Conference Research Vessels 2020 2020, p. 309.
- ^ Status Conference Research Vessels 2020 2020, p. 316.
- ^ Greene, Scofield & Dilks 2004, p. 20.
- ^ Furey, Ross-Sheppard & Prickett 2015, p. 516.
- ^ Anderson 2000, p. 118.
- ^ King 2010, p. 2.
- ^ King 2010, p. 1.
- ^ Broder et al. 1982, p. 43.
- ^ Gunn 1888, p. 604.
- ^ Crawford 1998, p. 132.
- ^ Higham & Johnson 1997, p. 207.
Sources
[edit]- Anderson, Atholl (2000). "Ceramics and Obsidian in Island Southeast Asia and Oceania Implications of prehistoric obsidian transfer in South Polynesia". Bulletin of the Indo-Pacific Prehistory Association. 20: 117–123.
- Barker, Simon J.; Rotella, Melissa D.; Wilson, Colin J. N.; Wright, Ian C.; Wysoczanski, Richard J. (1 August 2012). "Contrasting pyroclast density spectra from subaerial and submarine silicic eruptions in the Kermadec arc: implications for eruption processes and dredge sampling". Bulletin of Volcanology. 74 (6): 1425–1443. Bibcode:2012BVol...74.1425B. doi:10.1007/s00445-012-0604-2. ISSN 1432-0819. S2CID 128596293.
- Barkla, J. W.; Dilks, P. J.; Greene, T. C.; Griffiths, R. (1 September 2008). "Homalanthus polyandrus (Euphorbiaceae) on Macauley Island, southern Kermadec Islands, with notes on that island's vascular flora". New Zealand Journal of Botany. 46 (3): 373–379. Bibcode:2008NZJB...46..373B. doi:10.1080/00288250809509775. ISSN 0028-825X. S2CID 83866108.
- Beaumont, Jennifer; Rowden, Ashley Alun; Clark, Malcolm R. (2012). Deepwater biodiversity of the Kermadec Islands Coastal Marine Area (PDF) (Report). New Zealand Department of Conservation.
- Bourne, Anna J.; Sear, David A.; Langdon, Pete G.; Cronin, Shane J. (August 2023). "Developing a South Pacific tephra framework: Initial results from a Samoan Holocene sequence". Journal of Quaternary Science. 38 (6): 806–815. Bibcode:2023JQS....38..806B. doi:10.1002/jqs.3519. hdl:2292/66143.
- Braid, Heather E.; Bolstad, Kathrin S. R. (2019). "Cephalopod biodiversity of the Kermadec Islands: implications for conservation and some future taxonomic priorities". Invertebrate Systematics. doi:10.1071/IS18041. S2CID 145981591.
- Brook, F. J. (1 December 1999). "The coastal scleractinian coral fauna of the Kermadec Islands, southwestern Pacific Ocean". Journal of the Royal Society of New Zealand. 29 (4): 435–460. Bibcode:1999JRSNZ..29..435B. doi:10.1080/03014223.1999.9517606. ISSN 0303-6758.
- Brothers, R. N.; Martin, K. R. (1 March 1970). "The geology of Macauley island, Kermadec group, southwest Pacific". Bulletin Volcanologique. 34 (1): 330–346. Bibcode:1970BVol...34..330B. doi:10.1007/BF02597794. ISSN 1432-0819. S2CID 129097391.
- Casalbore, Daniele; Clare, Michael A.; Pope, Ed L.; Quartau, Rui; Bosman, Alessandro; Chiocci, Francesco L.; Romagnoli, Claudia; Santos, Rùben (23 April 2020). "Bedforms on the submarine flanks of insular volcanoes: New insights gained from high resolution seafloor surveys". Sedimentology. 68 (4): 1400–1438. doi:10.1111/sed.12725. hdl:11585/821228. ISSN 0037-0746. S2CID 216499847.
- Chinn, Warren GH (2015). "The Kermadec Islands terrestrial invertebrate fauna: Observations on the taxonomic distribution and island biogeography". Bulletin of the Auckland Museum. 20: 443–462 – via ResearchGate.
- Crawford, John (January 1998). "'A political H-Bomb': New Zealand and the British thermonuclear weapon tests of 1957–58". The Journal of Imperial and Commonwealth History. 26 (1): 127–150. doi:10.1080/03086539808583018. ISSN 0308-6534.
- de Lange, Peter J. (2015). "Recent vegetation succession and flora of Macauley Island, southern Kermadec Islands". Bulletin of the Auckland Museum (20): 207–230 – via ResearchGate.
- de Ronde, C. E. J.; Baker, E. T.; Massoth, G. J.; Lupton, J. E.; Wright, I. C.; Sparks, R. J.; Bannister, S. C.; Reyners, M. E.; Walker, S. L.; Greene, R. R.; Ishibashi, J.; Faure, K.; Resing, J. A.; Lebon, G. T. (July 2007). "Submarine hydrothermal activity along the mid-Kermadec Arc, New Zealand: Large-scale effects on venting". Geochemistry, Geophysics, Geosystems. 8 (7): n/a. Bibcode:2007GGG.....8.7007D. doi:10.1029/2006gc001495. ISSN 1525-2027. S2CID 128382122.
- de Ronde, C. E. J.; Chadwick, W. W.; Ditchburn, R. G.; Embley, R. W.; Tunnicliffe, V.; Baker, E. T.; Walker, S. L.; Ferrini, V. L.; Merle, S. M. (2015). "Molten Sulfur Lakes of Intraoceanic Arc Volcanoes". Volcanic Lakes. Springer. pp. 261–288. doi:10.1007/978-3-642-36833-2_11. ISBN 978-3-642-36833-2.
- Doyle, A. C.; Singleton, R. J.; Yaldwyn, J. C. (1 March 1979). "Volcanic activity and recent uplift on Curtis and Cheeseman Islands, Kermadec Group, Southwest Pacific". Journal of the Royal Society of New Zealand. 9 (1): 123–140. Bibcode:1979JRSNZ...9..123D. doi:10.1080/03036758.1979.10418159. ISSN 0303-6758.
- Dubinin, A. V.; Uspenskaya, T. Yu.; Gavrilenko, G. M.; Rashidov, V. A. (December 2008). "Geochemistry and genesis of Fe-Mn mineralization in island arcs in the west Pacific Ocean". Geochemistry International. 46 (12): 1206–1227. Bibcode:2008GeocI..46.1206D. doi:10.1134/S0016702908120021. ISSN 0016-7029. S2CID 128837789.
- Duffy, Clinton AJ; Baker, C. Scott; Constantine, Rochelle (2015). "Observation and identification of marine mammals during two recent expeditions to the Kermadec Islands, New Zealand". Bulletin of the Auckland Museum. 20 – via ResearchGate.
- Francis, Malcolm P.; Grace, Roger V.; Paulin, Chris D. (1 March 1987). "Coastal fishes of the Kermadec Islands". New Zealand Journal of Marine and Freshwater Research. 21 (1): 1–13. Bibcode:1987NZJMF..21....1F. doi:10.1080/00288330.1987.9516194. ISSN 0028-8330.
- Furey, L.; Ross-Sheppard, C.; Prickett, K. E. (2015). "Obsidian from Macualey Island: a new Zealand connection". Bull Auckl Mus. 20: 511–518.
- Gaskin, Chris (2011). Seabirds of the Kermadec region: Their natural history and conservation (PDF) (Report). New Zealand Department of Conservation.
- Gill, J.; Hoernle, K.; Todd, E.; Hauff, F.; Werner, R.; Timm, C.; Garbe-Schönberg, D.; Gutjahr, M. (February 2021). "Basalt Geochemistry and Mantle Flow During Early Backarc Basin Evolution: Havre Trough and Kermadec Arc, Southwest Pacific". Geochemistry, Geophysics, Geosystems. 22 (2). Bibcode:2021GGG....2209339G. doi:10.1029/2020gc009339.
- Glover, E. A. (1 August 2004). "Bathyaustriella Thionipta, A New Lucinid Bivalve from a Hydrothermal Vent on the Kermadec Ridge, New Zealand and ITS Relationship to Shallow-Water Taxa (Bivalvia: Lucinidae)". Journal of Molluscan Studies. 70 (3): 283–295. doi:10.1093/mollus/70.3.283.
- Gordon, Dennis P. (December 2014). "Apprehending novel biodiversity—fifteen new genera of Zealandian Bryozoa". Journal of the Marine Biological Association of the United Kingdom. 94 (8): 1597–1628. Bibcode:2014JMBUK..94.1597G. doi:10.1017/S0025315414000599. ISSN 0025-3154. S2CID 85336419.
- Greene, T. C.; Scofield, R. P.; Dilks, P. J. (2004). Status of Kermadec red-crowned parakeets and the likely effects of a proposed kiore eradication programme (PDF). DOC Science Internal Series. Vol. 179. ISBN 0-478-22579-2. ISSN 1175-6519.
- Gunn, John (1 November 1888). "The Kermadec Islands". Scottish Geographical Magazine. 4 (11): 599–604. doi:10.1080/14702548808555269. ISSN 0036-9225. S2CID 131632296.
- Higham, Thomas; Johnson, Leigh (October 1997). "The prehistoric chronology of Raoul Island, the Kermadec Group". Archaeology in Oceania. 32 (3): 207–213. doi:10.1002/j.1834-4453.1997.tb00389.x. ISSN 0728-4896.
- Holdaway, Richard N.; Anderson, Atholl (2001). Avifauna from the Emily Bay settlement site, Norfolk Island: a preliminary account (PDF) (Report). Vol. 53. Australian Museum. pp. 85–100.
- Holdaway, Richard N.; Worthy, Trevor H.; Tennyson, Alan J. D. (1 January 2001). "A working list of breeding bird species of the New Zealand region at first human contact". New Zealand Journal of Zoology. 28 (2): 119–187. doi:10.1080/03014223.2001.9518262. ISSN 0301-4223. S2CID 84423379.
- Keable, S.; Reid, A. (2015). "Marine invertebrates collected during the Kermadec Biodiscovery Expedition 2011". Bulletin of the Auckland Museum. 20: 263–310 – via ResearchGate.
- Proceedings Fact Sheet August 1, 2010 (PDF). The Kermadecs – Science Symposium. 2010. Retrieved 4 April 2022.
- King, Robert J. (2010). """The long wish'd for object"—Opening the Trade to Japan, 1785-1795."" (PDF). The Northern Mariner/Le Marin du Nord. 20 (1): 1–34. doi:10.25071/2561-5467.314. S2CID 247276991 – via Canadian Nautical Research Society.
- Kleint, Charlotte; Bach, Wolfgang; Diehl, Alexander; Fröhberg, Nico; Garbe-Schönberg, Dieter; Hartmann, Jan F.; de Ronde, Cornel E. J.; Sander, Sylvia G.; Strauss, Harald; Stucker, Valerie K.; Thal, Janis; Zitoun, Rebecca; Koschinsky, Andrea (5 December 2019). "Geochemical characterization of highly diverse hydrothermal fluids from volcanic vent systems of the Kermadec intraoceanic arc". Chemical Geology. 528: 119289. Bibcode:2019ChGeo.52819289K. doi:10.1016/j.chemgeo.2019.119289. ISSN 0009-2541. S2CID 202911910.
- Latter, J. H. (31 March 1985). "Frequency of eruptions at New Zealand volcanoes". Bulletin of the New Zealand Society for Earthquake Engineering. 18 (1): 55–110. doi:10.5459/bnzsee.18.1.55-110. ISSN 2324-1543. S2CID 132630684.
- Law, Garry (2008). Archaeology of the Bay of Plenty (Report). Science and Technical Publishing. New Zealand Department of Conservation – via Academia.edu.
- Liggins, Libby; Gleeson, Lachlan; Riginos, Cynthia (1 January 2014). "Evaluating edge-of-range genetic patterns for tropical echinoderms, Acanthaster planci and Tripneustes gratilla, of the Kermadec Islands, southwest Pacific". Bulletin of Marine Science. 90 (1): 379–397. doi:10.5343/bms.2013.1015. hdl:10179/17384.
- Lloyd, E. F.; Nathan, Simon; Smith, I. E. M.; Stewart, R. B. (1 June 1996). "Volcanic history of Macauley Island, Kermadec Ridge, New Zealand". New Zealand Journal of Geology and Geophysics. 39 (2): 295–308. Bibcode:1996NZJGG..39..295L. doi:10.1080/00288306.1996.9514713. ISSN 0028-8306.
- Mclay, Colin (9 July 2007). "New crabs from hydrothermal vents of the Kermadec Ridge submarine volcanoes, New Zealand: Gandalfus gen. nov. (Bythograeidae) and Xenograpsus (Varunidae) (Decapoda: Brachyura)". Zootaxa. 1524 (1): 1–22. doi:10.11646/zootaxa.1524.1.1 – via ResearchGate.
- McKay, Robert; Exon, Neville; Müller, Dietmar; Gohl, Karsten; Gurnis, Michael; Shevenell, Amelia; Henrys, Stuart; Inagaki, Fumio; Pandey, Dhananjai; Whiteside, Jessica; van de Flierdt, Tina; Naish, Tim; Heuer, Verena; Morono, Yuki; Coffin, Millard; Godard, Marguerite; Wallace, Laura; Kodaira, Shuichi; Bijl, Peter; Collot, Julien; Dickens, Gerald; Dugan, Brandon; Dunlea, Ann G.; Hackney, Ron; Ikehara, Minoru; Jutzeler, Martin; McNeill, Lisa; Naik, Sushant; Noble, Taryn; Opdyke, Bradley; Pecher, Ingo; Stott, Lowell; Uenzelmann-Neben, Gabriele; Vadakkeykath, Yatheesh; Wortmann, Ulrich G. (22 October 2018). "Developing community-based scientific priorities and new drilling proposals in the southern Indian and southwestern Pacific oceans". Scientific Drilling. 24: 61–70. Bibcode:2018SciDr..24...61M. doi:10.5194/sd-24-61-2018. hdl:1885/202787. ISSN 1816-8957. S2CID 54988937.
- Nelson, Wendy; Duffy, Clinton; Trnski, Thomas; Stewart, Rob (1 September 2018). "Mesophotic Ecklonia radiata (Laminariales) at Rangitāhua, Kermadec Islands, New Zealand". Phycologia. 57 (5): 534–538. Bibcode:2018Phyco..57..534N. doi:10.2216/18-9.1. ISSN 0031-8884. S2CID 90348258.
- Nisbet, Ian CT (1979). Conservation of marine birds of northern North America-a summary (Report). Wildlife Research Report 11. pp. 305–315 – via Google Books.
- Rotella, Melissa D.; Wilson, Colin J. N.; Barker, Simon J.; Ian Schipper, C.; Wright, Ian C.; Wysoczanski, Richard J. (15 August 2015). "Dynamics of deep submarine silicic explosive eruptions in the Kermadec arc, as reflected in pumice vesicularity textures". Journal of Volcanology and Geothermal Research. 301: 314–332. Bibcode:2015JVGR..301..314R. doi:10.1016/j.jvolgeores.2015.05.021. ISSN 0377-0273.
- Schnabel, Kareen E.; Bruce, Niel L. (13 April 2006). "New records of Munidopsis (Crustacea: Anomura: Galatheidae) from New Zealand with description of two new species from a seamount and underwater canyon". Zootaxa. 1172 (1): 49. doi:10.11646/zootaxa.1172.1.5 – via ResearchGate.
- Shane, Phil; Wright, Ian C. (27 April 2011). "Late Quaternary tephra layers around Raoul and Macauley Islands, Kermadec Arc: implications for volcanic sources, explosive volcanism and tephrochronology". Journal of Quaternary Science. 26 (4): 422–432. Bibcode:2011JQS....26..422S. doi:10.1002/jqs.1468. ISSN 0267-8179. S2CID 247703984.
- Shane, Phil (2017). "The Southern End of the Pacific Ring of Fire: Quaternary Volcanism in New Zealand". Landscape and Quaternary Environmental Change in New Zealand. Atlantis Press. pp. 35–66. doi:10.2991/978-94-6239-237-3_2. ISBN 978-94-6239-237-3.
- Broder, Sherry; Van Dyke, Jon; Kimura, Faye; Hirayasu, Naomi (1982). "Ocean Boundaries in the South Pacific". U. Haw. L. Rev. – via HeinOnline.
- Smith, Ian E. M.; Worthington, Timothy J.; Stewart, Robert B.; Price, Richard C.; Gamble, John A. (1 January 2003). "Felsic volcanism in the Kermadec arc, SW Pacific: crustal recycling in an oceanic setting". Geological Society, London, Special Publications. 219 (1): 99–118. Bibcode:2003GSLSP.219...99S. doi:10.1144/GSL.SP.2003.219.01.05. ISSN 0305-8719. S2CID 140676351.
- Smith, Ian E. M.; Stewart, Robert B.; Price, Richard C. (1 June 2003). "The petrology of a large intra-oceanic silicic eruption: the Sandy Bay Tephra, Kermadec Arc, Southwest Pacific". Journal of Volcanology and Geothermal Research. 124 (3): 173–194. Bibcode:2003JVGR..124..173S. doi:10.1016/S0377-0273(03)00040-4. ISSN 0377-0273.
- Song, Yann-huei (3 July 2018). "The July 2016 Arbitral Award, Interpretation of Article 121(3) of the UNCLOS, and Selecting Examples of Inconsistent State Practices". Ocean Development & International Law. 49 (3): 247–261. doi:10.1080/00908320.2018.1479355. ISSN 0090-8320. S2CID 158956817.
- Proceedings (PDF). Status Conference Research Vessels 2020. 2020. Retrieved 4 April 2022.
- Sykes, W. R. (1969). "The Effect of Goats on Vegetation of the Kermadec Islands". Proceedings of the New Zealand Ecological Society (16): 13–16. ISSN 0077-9946. JSTOR 24061357.
- Timm, Christian; de Ronde, Cornel E. J.; Leybourne, Matthew I.; Layton-Matthews, Daniel; Graham, Ian J. (1 December 2012). "Sources of Chalcophile and Siderophile Elements in Kermadec Arc Lavas*". Economic Geology. 107 (8): 1527–1538. Bibcode:2012EcGeo.107.1527T. doi:10.2113/econgeo.107.8.1527. ISSN 0361-0128.
- Veitch, C. R.; Miskelly, C. M.; Harper, G. A.; Taylor, G. A.; Tennyson, A. J. (2004). "Birds of the Kermadec Islands, south-west Pacific". Notornis. 51 (2): 61–90 – via ResearchGate.
- Von Cosel, Rudo; Marshall, Bruce A. (2010). "A new genus and species of large mussel (Mollusca: Bivalvia: Mytilidae) from the Kermadec Ridge". Nautilus. 117: 31–46.
- Williams, G. R.; Rudge, M. R. (1969). "A Population Study of Feral Goats (Capra Hircus L.), from Macauley Island, New Zealand". Proceedings of the New Zealand Ecological Society (16): 17–28. ISSN 0077-9946. JSTOR 24061358.
- Worthington, Tim J; Gregory, Murray R; Bondarenko, Vladislav (1 May 1999). "The Denham Caldera on Raoul Volcano: dacitic volcanism in the Tonga–Kermadec arc". Journal of Volcanology and Geothermal Research. 90 (1): 29–48. Bibcode:1999JVGR...90...29W. doi:10.1016/S0377-0273(99)00018-9. ISSN 0377-0273.
- Wright, I. C.; Worthington, T. J.; Gamble, J. A. (15 January 2006). "New multibeam mapping and geochemistry of the 30°–35° S sector, and overview, of southern Kermadec arc volcanism". Journal of Volcanology and Geothermal Research. 149 (3): 263–296. Bibcode:2006JVGR..149..263W. doi:10.1016/j.jvolgeores.2005.03.021. ISSN 0377-0273.
- Wyville Thomson, C.; Murray, J. (1 January 1885). The Voyage of H.M.S. Challenger 1873-1876. Narrative Vol. I. First Part. Chapter XII.
External links
[edit]- "Macauley Island". Global Volcanism Program. Smithsonian Institution.
- Boschen, Rachel E.; Rowden, Ashley A.; Clark, Malcolm R.; Gardner, Jonathan P. A. (2015). "Limitations in the Use of Archived Vent Mussel Samples to Assess Genetic Connectivity Among Seafloor Massive Sulfide Deposits: A Case Study with Implications for Environmental Management". Frontiers in Marine Science. 2. doi:10.3389/fmars.2015.00105. ISSN 2296-7745.
- Kleint, Charlotte; Zitoun, Rebecca; Neuholz, René; Walter, Maren; Schnetger, Bernhard; Klose, Lukas; Chiswell, Stephen M.; Middag, Rob; Laan, Patrick; Sander, Sylvia G.; Koschinsky, Andrea (2022). "Trace Metal Dynamics in Shallow Hydrothermal Plumes at the Kermadec Arc". Frontiers in Marine Science. 8. doi:10.3389/fmars.2021.782734. ISSN 2296-7745.
- Department of Conservation - Kermadec Islands page
- Map of Macauley and Giggenbach submarine volcanoes—Picture of island and article by Ian Wright, Ocean Geology, National Institute of Water and Atmospheric Research, Wellington, New Zealand
- Te Ara - the Encyclopedia of New Zealand - "The last goat on Macauley Island"
- Islands of the Kermadec Islands
- Volcanic islands of New Zealand
- VEI-7 volcanoes
- Volcanoes of the New Zealand outlying islands
- Calderas of New Zealand
- Submarine calderas
- Holocene calderas
- Quaternary Oceania
- Inactive volcanoes
- Uninhabited islands of New Zealand
- Island restoration
- Important Bird Areas of the Kermadec Islands