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Microlite Size Distributions and P-T-t-x (H2O) constraints of Central Plateau tephras, New Zealand: implications for magma ascent processes of explosive eruptions
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  • Charline Lormand,
  • Georg Zellmer,
  • Geoff Kilgour,
  • Yoshiyuki Iizuka,
  • Stuart Mead,
  • Naoya Sakamoto,
  • Karoly Nemeth,
  • Alan Palmer,
  • Anja Moebis,
  • Takeshi Kuritani,
  • Hisayoshi Yurimoto
Charline Lormand
Volcanic Risk Solutions, Massey University

Corresponding Author:c.lormand@massey.ac.nz

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Georg Zellmer
Volcanic Risk Solutions, Massey University
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Geoff Kilgour
GNS Science Wairakei
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Yoshiyuki Iizuka
Institute of Earth Sciences, Academia Sinica, Taipei, Taiwan
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Stuart Mead
Volcanic Risk Solutions, Massey University
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Naoya Sakamoto
Creative Research Institute, Isotope Imaging Laboratory, Hokkaido University
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Karoly Nemeth
Volcanic Risk Solutions, Massey University
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Alan Palmer
Department of Soil Science, Massey University
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Anja Moebis
Department of Soil Science, Massey University
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Takeshi Kuritani
Graduate School of Science, Hokkaido University
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Hisayoshi Yurimoto
4Creative Research Institute, Isotope Imaging Laboratory, Hokkaido University
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Abstract

Crystals within erupted volcanic rocks record geochemical and textural signatures during magmatic evolution prior to the onset of eruptions. Growth times of microlites can be derived through Crystal Size Distribution (CSD) analysis combined with well-constrained microlite growth rates, yielding petrologically-determined magma ascent timescales. Our newly developed, machine learning image processing scheme allows for the rapid generation of CSD, saving many hours of processing time, which previously involved hand-drawing the outer margins of crystals. For the present study, we examined a range of andesitic tephras from the Tongariro Volcanic Centre, New Zealand. A total of 228 plagioclase and pyroxene microlites CSDs were generated from individual tephra shards. All combined pyroxene and plagioclase microlite CSDs exhibit concave-up shapes, and similar intercepts and slopes at the smallest sizes. This implies similar growth durations of the smallest microlites of 15±9 to 28±15 (2σ) hours, regardless of the eruptive style or source, using an orthopyroxene microlite growth rate constrained from one of the samples. The orthopyroxene thermometer and the plagioclase hygrometer reveal the magmas were erupted at ~ 1079 to 1149 (±39 SEE), and H2O contents ranging from 0-0.4 to 0-1.7 wt.% (95% confidence maxima). In the absence of CO2, these results indicate shallow H2O exsolution pressures of < 240 bars, using a recent H2O-CO2 solubility model. Given the microlite residence times, shallow H2O exsolution driving microlite growth is inconsistent with the explosivity of the eruptions. Instead, our data suggest that the melts either carried large amounts of CO2, triggering earlier degassing of volatiles including H2O, or that microlite crystallisation began prior to degassing. Ongoing work investigates the H2O and CO2 contents hosted by melt inclusions in phenocrysts and microphenocrysts in these tephras to provide constraints on magma ascent rates, with implications for hazard characterization and mitigation.