Volcano-tectonic interactions at the southern margin of the Okataina Volcanic Centre, Taupō Volcanic Zone, New Zealand

• Published in: Journal of volcanology and geothermal research Vol. 427; p. 107552
• Main Authors: Berryman, Kelvin, Villamor, Pilar, Nairn, Ian, Begg, John, Alloway, Brent V., Rowland, Julie, Lee, Julie, Capote, Ramon
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2022
• Subjects: Ngapouri-Rotomahana Fault; Okataina Volcanic Centre; Paeroa Fault; Paleoseismology; Rhyolite eruption; Tephra; Volcano-tectonic interaction; Paeroa Fault; Tephra; Volcano-tectonic interaction; Ngapouri-Rotomahana Fault; Rhyolite eruption; Okataina Volcanic Centre; Paleoseismology
• ISSN: 0377-0273; 1872-6097
• DOI: 10.1016/j.jvolgeores.2022.107552

The c. 15 km-long Ngapouri-Rotomahana Fault (NRF) is a major splay of the Paeroa Fault at the eastern margin of the modern Taupō Rift, the active tectonic structure embedded within the Taupō Volcanic Zone of North Island, New Zealand. The NRF and Paeroa Fault extend to the southern margin of the Okataina Volcanic Centre (OVC) and lie southwest of the Tarawera vent lineation, which is the source of approximately half of the eruptions of the OVC in the past 25 cal. ka BP. Here, we explore volcano-tectonic relationships between the OVC and the NRF and Paeroa Fault. Collective evidence used in our analysis includes: volcanic processes interpreted as occurring during the historic 1886 Tarawera (basalt) and the prehistoric 1314 ± 12 CE Kaharoa (basalt triggered rhyolite) eruptions, both on the Tarawera vent lineation; exposures in five trenches excavated across the NRF and seven trenches across the Paeroa Fault; data on a series of explosion craters formed to the southwest of the volcano associated with the ~1314 CE Kaharoa eruption and the Rotoma rhyolite (~9.4 cal. ka BP) eruption from the OVC; and mafic dykes that primed several of the OVC eruptions. Data from the twelve trenches on the two faults reveal eight surface fault ruptures since 15.6 cal. ka BP, with most closely coinciding with volcanic eruptions, providing a first-order indication of probable causality. Three principal modes of interaction are identified. Firstly, large displacement events on the Paeroa fault, arguably immediately prior to the Mamaku and Rotoma rhyolite eruptions (~7.9 and ~9.4. cal. ka BP, respectively) and on the NRF immediately prior to the ~1314 CE Kaharoa eruption are candidates for earthquake static or dynamic stress triggers for those explosive eruptive events. Secondly, basalt dyke intrusion was also involved in the initiation of the Kaharoa eruption, so the spatial and temporal relationships between dyke intrusion, smaller displacement fault ruptures and initiation of the Kaharoa eruption appear closely connected. Thirdly, faulting events that are interpreted as co- or post-eruption may be the result of stress triggers associated with magma chamber deflation. •Spatial and temporal associations between fault ruptures and eruptions indicate linked processes.•Fault ruptures occur immediately before, during and shortly after volcanic eruptions.•Static stress transfer is a likely trigger between fault rupture and volcanic eruption or caldera deflation.•Basalt dykes interact with active faults at caldera margins as well as rhyolite magma chambers.