Contrasting punctuated zircon growth in two syn-erupted rhyolite magmas from Tarawera volcano: Insights to crystal diversity in magmatic systems |
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| Authors: | Sonja Storm Phil Shane Axel K Schmitt Jan M Lindsay |
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| Institution: | 1. School of Geography, Environment and Earth Sciences, Victoria University, Wellington 6140, New Zealand;2. GNS Science, Wairakei Research Centre, Taupo 3377, New Zealand;3. Mighty River Power Ltd., PO Box 90399, Auckland 1142, New Zealand;4. CEPSAR, The Open University, Walton Hall, Milton Keynes MK7 6AA, United Kingdom;5. SUMAC, Stanford University, Stanford, CA 94305-2220, USA;6. Research School of Earth Sciences, Australian National University, Canberra, ACT 0200, Australia;1. School of Geography, Environment and Earth Sciences, Victoria University, PO Box 600, Wellington 6140, New Zealand;2. Environment Approvals Division, Department of Agriculture, Water and the Environment, PO Box 787, Canberra 2601, Australia;3. School of Biological, Earth and Environmental Science, University College Cork, Ireland;4. GNS Science, Avalon Research Centre, PO Box 30368, Lower Hutt 5045, New Zealand |
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| Abstract: | Two mineralogically and chemically distinct rhyolite magmas (T1 and T3) were syn-erupted from the same conduit system during the 21.9 ka basalt intrusion-triggered Okareka eruption from Tarawera volcano, New Zealand. High spatial resolution U–Th disequilibrium dating of zircon crystals at the ~ 3–5 μm scale reveals a protracted yet discontinuous zircon crystallization history within the magmatic system. Both magma types contain zircon whose interiors predate the eruption by up to 200 ka. The dominant age peak in the T1 magma is ~ 30 ka with subordinate peaks at ~ 45, ~ 75, and ~ 100 ka, whereas the T3 magma has a dominant zircon interior age peak at ~ 90 ka with smaller modes at ~ 35 and ~ 150 ka. These patterns are consistent with isolated pockets of crystallization throughout the evolution of the system. Crystal rim analyses yield ages ranging from within error of the eruption age to at least ~ 90 ka prior to eruption, highlighting that zircon crystallization frequently stalled long before the eruption. Continuous depth profiling from crystal rims inward demonstrates protracted growth histories for individual crystals (up to ~ 100 ka) that were punctuated by asynchronous hiatuses of up to 30 ka in duration. Disparate zircon growth histories can result from localized thermal perturbations caused by mafic intrusions into a silicic reservoir. The crystal age heterogeneity at hand-sample scale requires considerable crystal transport and mixing. We propose that crystal mixing was achieved through buoyancy instabilities caused by mafic magma flow through crystal mush. A terminal pre-eruptive rejuvenation event was capable of mobilizing voluminous melts that erupted, but was too short (< 102–103 years) to result in extensive zircon growth. The contrasting, punctuated zircon histories argue against closed-system fractional crystallization models for silicic magmatism that require protracted cooling times following a mostly liquid starting condition. |
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