The browser you are using is not supported by this website. All versions of Internet Explorer are no longer supported, either by us or Microsoft (read more here:

Please use a modern browser to fully experience our website, such as the newest versions of Edge, Chrome, Firefox or Safari etc.

AN picture

Andreas Nilsson

Senior lecturer

AN picture

Constraining the eruption history of Rangitoto volcano, New Zealand, using palaeomagnetic data


  • Megan L. Allington
  • Andreas Nilsson
  • Mimi J. Hill
  • Neil Suttie
  • Dimitra Daniil
  • Ingeborg Hjorth
  • Linda Aulin
  • Paul C. Augustinus
  • Phil Shane

Summary, in English

New Zealand's largest city, Auckland, is situated within the basaltic Auckland Volcanic Field (AVF). Therefore, understanding the eruption history of the local volcanoes in the field is of great importance in order to assess future hazards that they may pose. Rangitoto is the youngest and largest volcano in the AVF, although the timing of the first eruption and the duration of the volcanic activity are still uncertain. Here, we use palaeomagnetic methods to provide additional constraints to the duration of the main shield-building phase of Rangitoto, previously estimated to have lasted either less than 100 years or approximately 1000 years. Lava flow samples from an ∼140 m length vertically oriented drill core produced 203 palaeoinclinations and 74 palaeointensity estimates. Our results show significant variation in both inclination (up to 30°) and intensities (which fall between 25 and 60 μT; present day field values for Auckland are ∼55 μT). Potential non-geomagnetic explanations for these variations, including thermochemical processes and rheological deformation are discussed. A statistical model was created to determine the minimum duration for the construction of Rangitoto that is compatible with the variations in the palaeomagnetic data, using prior information about the rate of change of the geomagnetic field. We conclude that the palaeomagnetic data are incompatible with the previously suggested short duration (under 100 years) of the shield-building phase and suggest instead a range of 150–450 years, when also accounting for the available radiocarbon ages. Given these results, this has implications for the timing, and thus impact of possible future eruptions in the AVF.


  • Quaternary Sciences

Publishing year





Quaternary Geochronology



Document type

Journal article




  • Geology


  • Magnetic inclination
  • Palaeointensity
  • Southern hemisphere
  • Volcanology




  • ISSN: 1871-1014