Matukutūreia / McLaughlins Mountain explained

Matukutūreia / McLaughlins Mountain
Elevation M:73
Location:North Island, New Zealand
Coordinates:-37.0135°N 174.846°W
Age:48,000 ± 3000 years[1]
Volcanic Field:Auckland volcanic field
Last Eruption:48,000 years

Matukutūreia / McLaughlins Mountain is one of the volcanic cones in the Auckland volcanic field. It has a peak 73 metres above sea level, and was the site of a pā. The scoria cone was originally crescent-shaped and featured Māori terraces and kumara pits, before extensive quarrying reduced it to a pyramid-shaped mound big enough to support the summit water tank for Papatoetoe. A small part of the summit and the eastern side of the cone were left unquarried, plus a large area of lava flows to the south of the cone remains intact. These remaining parts have recently been transferred to Department of Conservation Management, primarily because of the high heritage values of the Matukuturua Stonefields gardens.

Matukutūreia and nearby Wiri Mountain are collectively known as Matukurua (also Ngā Matukurua).[2]

From July to September 2010, the water tank was removed from the top of Matukutūreia / McLaughlins Mountain, as part of an agreement when the land was handed over to the Department of Conservation.

Geology

Matukutūreia / McLaughlins Mountain is a spatter cone associated with the Matukuturua lava field,[1] and has geophysical features that raised the possibility of it being a rootless cone, with no apparent gravitational or magnetic evidence of a residual lava conduit but a uniform best-fit magnetic declination of about 20° west implying a short eruption.[3] Rootless cones can form when a lava flow flows over a localised water accumulation but the surface of the lava flow solidifies allowing continuing explosive tephra eruptions from the interactions of heat, lava and steam to form a cone.[4] Later work by the same group clarified that Matukutūreia / McLaughlins Mountain itself had a 140 nT peak to peak magnetic anomaly, but four eruption craters to its west and south-west towards the Puhinui Reserve are not associated with any magnetic anomaly.[5] One of these the Matukuturua explosion crater is within the Matukuturua lava field and only from Matukutūreia / McLaughlins Mountain was definitely formed by a single steam event.[1] This is consistent with the observations elsewhere on the mechanism of rootless cone formation but also in the case of the explosion crater a phreatic eruption scenario where magma never reaches the surface.[1] The three Puhinui Craters are maar structures and also could have the same origin but this is not known to be the case. The source of the Matukuturua lava is assigned to the extensively quarried Matukutūreia / McLaughlins Mountain, which therefore has a root, and the Matukuturua crater has been incorporated in the reserve area as a result of these unusual properties for an Auckland volcanic field crater.[1]

References

Sources

External links

Notes and References

  1. Technical Report 6:Geological evaluation Mclaughins Quarry private plan change request Geological evaluation of outstanding natural feature: Matukutūreia and Matukuturua lava field and tuff ring. 2019. S.. Cronin. 10 February 2024. https://web.archive.org/web/20240210153832/https://www.aucklandcouncil.govt.nz/UnitaryPlanDocuments/pc43-technical-report-6-geological-evaluation-report.pdf. 10 February 2024. 1–23.
  2. Manurewa Marae Website "A Tale of Manurewa"
  3. Rout. D.J.. Cassidy. J.. Locke. C.A.. Smith. I.E.. 1993. Geophysical evidence for temporal and structural relationships within the monogenetic basalt volcanoes of the Auckland volcanic field, northern New Zealand. Journal of Volcanology and Geothermal Research. 57. 1-2. 71–83. 10.1016/0377-0273(93)90032-M. 1993JVGR...57...71R.
  4. Burr. Devon M.. Bruno. Barbara C.. Lanagan. Peter D.. Glaze. Lori S.. Jaeger. Windy L.. Soare. Richard J.. Wan Bun Tseung. Jean-Michel. Skinner. James A.. Baloga. Stephen M.. Mesoscale raised rim depressions (MRRDs) on Earth: A review of the characteristics, processes, and spatial distributions of analogs for Mars. Planetary and Space Science. 57. 5–6. 579–596. 10.1016/j.pss.2008.11.011. 2009. 2009P&SS...57..579B.
  5. Cassidy. J.. Locke. C.A.. Miller. C.A.. Rout. D.J.. 1999. The Auckland volcanic field, New Zealand: geophysical evidence for its eruption history.. Geological Society, London, Special Publications. 161. 1. 1–10. 1999GSLSP.161....1C. 10.1144/GSL.SP.1999.161.01.02.