Time scales of olivine storage and transport as revealed by diffusion chronometry at Waitomokia Volcanic Complex, Auckland Volcanic Field, New Zealand

IF 2.4 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Journal of Volcanology and Geothermal Research Pub Date : 2024-05-12 DOI:10.1016/j.jvolgeores.2024.108094
Rosa Didonna , Heather Handley , Helena Albert , Fidel Costa
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Abstract

Detailed knowledge of the pre-eruptive time scales associated with magma storage and transport is vital to improve volcanic hazard forecasting in active volcanic regions. However, quantification of the timescales of volcanic processes at mafic volcanic centres in continental intraplate settings is challenging, despite them being a source of significant hazards for human populations and infrastructure due to their limited predictability in space and time. We conducted a detailed petrological study to investigate the time scales of olivine storage and transfer throughout the eruption sequence of Waitomokia Volcanic Complex, a tuff ring and scoria cone complex in the Auckland Volcanic Field. Olivine crystal textures and compositions were determined from stratigraphically-constrained samples of the volcanic complex, from the initial phreatomagmatic phase to the final magmatic phase. Olivine crystals are typically <300 μm in length and characterised by skeletal morphologies, displaying chemical zoning in forsterite (Fo = 100*Mg/[Mg + Fe]; mol%), CaO, MnO and NiO wt% contents. We classified olivine into three major groups based on their Fo core compositions: (1) normally zoned crystals with high Fo content (Fo > 85), (2) crystals with intermediate Fo contents (84–81), and (3) reversely zoned crystals with lower Fo core content (<80). Olivine chemical zoning (diffusion) profiles were modelled in the context of a specific magmatic environment linked with changes in thermodynamic variables during storage (temperature, pressure, and oxygen fugacity). We propose that the normally zoned olivine crystals grew in one magmatic environment (ME1), which subsequently intruded into a more evolved (lower MgO) environment (ME2), where they interacted and were stored for up to 135 days before their eruption. During magma ascent to the surface, a second magma mixing event occurred between ME2 and magma within a third magmatic environment (ME3), forming reversely-zoned olivine crystals yielding notably shorter ascent times of approximately a few days. The rocks from the opening phreatomagmatic phase of the eruption show a larger range in olivine group types compared to the final magmatic phase, where those from the deeper ME1 are more abundant. The short time scales of magma transport obtained in our study, on the order of days to months, should be informative of the warning times that may be encountered between the onset of volcanic unrest and an eruption in the Auckland Volcanic Field.

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新西兰奥克兰火山场怀托莫基亚火山群扩散计时法揭示的橄榄石储存和迁移时间尺度
详细了解与岩浆储存和运输相关的爆发前时间尺度,对于改进活火山地区的火山灾害预报至关重要。然而,对大陆板块内环境中的岩浆火山中心的火山过程时间尺度进行量化具有挑战性,尽管由于其在空间和时间上的可预测性有限,它们是对人类和基础设施造成重大危害的根源。我们开展了一项详细的岩石学研究,以调查奥克兰火山场怀托莫基亚火山群(一个凝灰岩环和灼热锥复合体)整个喷发序列中橄榄石储存和转移的时间尺度。从最初的喷气岩浆阶段到最后的岩浆阶段,对火山群的地层限制样本进行了橄榄石晶体纹理和成分测定。橄榄石晶体的长度通常为 300 微米,具有骨架状形态,并显示出沸石(Fo = 100*Mg/[Mg + Fe]; mol%)、氧化钙、氧化锰和氧化镍重量百分比含量的化学分区。我们根据橄榄石的 Fo 核心成分将其分为三大类:(1) Fo 含量高(Fo > 85)的正常分带晶体;(2) Fo 含量居中(84-81)的晶体;(3) Fo 核心含量较低(<80)的反向分带晶体。橄榄石化学分带(扩散)剖面是在特定岩浆环境下,结合贮存期间热力学变量(温度、压力和氧富集度)的变化而建立的模型。我们认为,正常分带的橄榄石晶体生长在一个岩浆环境(ME1)中,随后侵入到一个更进化(氧化镁含量更低)的环境(ME2)中,在那里它们相互作用,并在喷发前储存了长达 135 天。在岩浆上升到地表的过程中,ME2 和第三个岩浆环境(ME3)中的岩浆发生了第二次岩浆混合,形成了反向分带的橄榄石晶体,使上升时间明显缩短,约为几天。与最后岩浆阶段相比,喷发初期的岩浆阶段的岩石显示出更大范围的橄榄石组类型,而在最后岩浆阶段,来自更深的 ME1 的橄榄石组类型更为丰富。我们的研究获得的岩浆迁移时间尺度很短,大约为几天到几个月,这应该能够说明奥克兰火山区从火山动荡开始到火山爆发之间的预警时间。
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来源期刊
CiteScore
5.90
自引率
13.80%
发文量
183
审稿时长
19.7 weeks
期刊介绍: An international research journal with focus on volcanic and geothermal processes and their impact on the environment and society. Submission of papers covering the following aspects of volcanology and geothermal research are encouraged: (1) Geological aspects of volcanic systems: volcano stratigraphy, structure and tectonic influence; eruptive history; evolution of volcanic landforms; eruption style and progress; dispersal patterns of lava and ash; analysis of real-time eruption observations. (2) Geochemical and petrological aspects of volcanic rocks: magma genesis and evolution; crystallization; volatile compositions, solubility, and degassing; volcanic petrography and textural analysis. (3) Hydrology, geochemistry and measurement of volcanic and hydrothermal fluids: volcanic gas emissions; fumaroles and springs; crater lakes; hydrothermal mineralization. (4) Geophysical aspects of volcanic systems: physical properties of volcanic rocks and magmas; heat flow studies; volcano seismology, geodesy and remote sensing. (5) Computational modeling and experimental simulation of magmatic and hydrothermal processes: eruption dynamics; magma transport and storage; plume dynamics and ash dispersal; lava flow dynamics; hydrothermal fluid flow; thermodynamics of aqueous fluids and melts. (6) Volcano hazard and risk research: hazard zonation methodology, development of forecasting tools; assessment techniques for vulnerability and impact.
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