Abstract
Constraining the process by which volcanoes become unstable is difficult. Several models have been proposed to explain the driving forces which cause volcanic edifices to catastrophically collapse. These include models for destabilisation of volcanic flanks by wedging due to dyke intrusion and the weakening of mechanical properties by pressurisation of pore fluids. It is not known which, if any, of the models are relevant to particular sector collapse events. Recent developments in the palaeomagnetic estimation of emplacement temperatures of volcaniclastic rocks have shown that even relatively low emplacement temperatures can be recorded by volcaniclastics with high fidelity. We have carried out a palaeomagnetic study of emplacement temperatures to investigate the role of igneous activity in the initiation of the 9,500 b.p. Murimotu sector collapse of Mt Ruapehu, New Zealand. This debris avalanche deposit has three fades which are stratigraphically superimposed, and the lowermost fades contains three lithological assemblages representing different segments of the edifice which were transported with little internal mixing within the flow. We have determined that some of the dacite-bearing assemblage 1, fades 1 was hot (∼350 °C) during transport and emplacement, whereas none of the other lithological assemblages of fades contained hot material. Our interpretation is that a dacite dome was active on the ancient Ruapehu edifice immediately prior to the Murimotu sector collapse. The partially cooled carapace of the dome and material shed from this part was incorporated into the avalanche deposit, along with cold lavas and volcaniclastics. We have not found evidence for incorporation of material at or close to magmatic temperatures, at least in the sampled locations. Our palaeomagnetic work allows us to develop a comprehensive, new palaeomagnetic classification of volcaniclastics.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aramaki S, Akimoto S (1957) Temperature estimation of pyroclastic deposits by natural remanent magnetization. Am J Sci 255:619–627
Bardot L, Thomas R, McClelland E (1996) Emplacement temperatures of pyroclastic deposits on Santorini deduced from palaeomagnetic mechanisms: constraints on eruption mechanisms. In: Morris A, Tarling DH (eds) 1996, palaeomagnetism and tectonics of the Mediterranean region. Geol Soc Spec Publ 105:354–357
Clement BM, Connor CB, Graper G (1993) Palaeomagnetic estimate of the emplacement temperature of the long-runout Nevado de Colima volcanic debris avalanche deposit, Mexico. ESPL 120:499–510
Day SJ (1996) Hydrothermal pore fluid pressure and the stability of porous, permeable volcanoes. In: McGuire WJ, Jones AP, Neuburg J (eds) Volcano instability on the Earth and other planets. Geol Soc Lond Spec Publ 110:77–93
Donoghue SL, Neall VE, Palmer AS, Stewart RB (1997) The volcanic history of Ruapehu during the past 2 millennia based on the record of Tufa Trig tephras. Bull Volcanol 59:136–146
Elsworth D, Voight B (1996) Evaluation of volcano flank instability triggered by dyke intrusion. In: McGuire VVJ, Jones AP, Neuburg J (eds) Volcano instability on the Earth and other planets. Geol Soc Lond Spec Publ 110:45–53
Hakett WR, Houghton BF (1989) A fades model for a Quaternary andesitic composite volcano: Ruapehu, New Zealand. Bull Volcanol 51:51–68
Hoblitt RP, Kellogg KS (1979) Emplacement temperatures of unsorted and unstratified deposits of volcanic rock debris as determined by palaeomaiznetic techniques. Geol Soc Am Bull 90:633–642
Kent DV, Ninkovich D, Pescatore T, Sparks SRJ (1981) Palaeomagnetic determination of emplacement temperature of Vesuvius AD 79 pyroclastic deposits. Nature 290:393–396
Kent JT, Briden JC, Mardia KV (1983) Linear and planar structure in ordered multivariate data as applied to progressive demagnetization of palaeomagnetic remanence. Geophvs J R Astron Soc 62:699–718
McClelland Brown E (1982) Discrimination of TRM and CRM by blocking temperature spectrum analysis. Phys Earth Planet Interiors 30:405–414
McClelland EA, Druitt TH (1989) Palaeomagnetic estimates of emplacement temperatures of pyroclastic deposits on Santorini, Greece. Bull Volcanol 51:16–27
McFadden PL, McElhinny MW (1988). The combined analysis of remagnetization circles and direct observations in palaeomagnetism. Earth Planet Sci Lett 87:161–172
McGuire WJ (1996) Volcano instability: a review of contemporary themes. In: McGuire WJ, Jones AP, Neuburg J (eds) Volcano instability on the Earth and other planets. Geol Soc Lond Spec Publ 110:1–23
McGuire WJ, Howarth RJ, Firth CR, Solow AR, Pullen AD, Saunders SJ, Stewart IS, Vita-Finzi C (1997) Correlation between rate of sea-level change and frequency of explosive volcanism in the Mediterranean. Nature 389:473–476
Moore JG, Clague D, Holcomb R, Lipman P, Normark WR (1989) Prodidous submarine landslides on the Hawaiian ridge. J Geophys Res 94:17465–17484
Palacious D (1994) The origin of certain wide valleys in the Canary Islands. Geomorphology 9:1–18
Palmer BA, Neall VE (1989) The Murimotu Formation − 9500 year old deposits of a debris avalanche and associated lahars. Mount Ruapehu, North Island, New Zealand. N Z J Geol Geophvs 32:477–486
Pullaiah G, Irving E, Buchan KL, Dunlop DJ (1975) Magnetization changes caused by burial and uplift. Earth Planet Sci Lett 28:133–134
Siebert L (1984) Large volcanic debris avalanches: characteristics of source areas, deposits and associated eruptions. J Volcanol Geotherm Res 22:163–197
Tamura Y, Koyama M, Fiske RS (1991) Palaeomagnetic evidence for hot pyroclastic debris flow in the shallow submarine Shirahama Group (Upper Miocene-Pliocene) Japan. J Geophvs Res 96 B13:2179–2178
Ui T (1983) Volcanic dry avalanche deposits — identification and comparison with non-volcanic debris stream deposits. In: Aramaki S, Kushiro I (eds) Arc volcanism. J Volcanol Geotherm Res 18:135–150
Voight B, Glicken H, Janda RJ, Douglas PM (1981) Catastrophic rocksiide avalanche of May 18th 1980. In: Lipman PW, Mullineaux D (eds) The 1980 eruptions of Mount St. Helens, Washington. US Geol Surv Prof Pap 1250:347–378
Voight B, Janda RJ, Glicken H. Douglas PM (1983) The nature and mechanics of the Mount St. Helens rockslide-avalanche of 18th May 1980. Geotechnique 33:243–273
Author information
Authors and Affiliations
Corresponding author
Additional information
Published online: 25 January 2003
Editorial responsibility: D. Dingwell
Rights and permissions
About this article
Cite this article
McClelland, E., Erwin, P.S. Was a dacite dome implicated in the 9,500 b.p. collapse of Mt Ruapehu? A palaeomagnetic investigation. Bull Volcanol 65, 294–305 (2003). https://doi.org/10.1007/s00445-002-0261-y
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/s00445-002-0261-y