Magma Evolution and Storage Conditions in an Andesite-Dacite Volcanic System, Whakaari (White Island), New Zealand

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Wei-Cheng Jiang, John Adam, Chris Firth, Simon Turner, Tracy Rushmer, Shane Cronin
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Abstract

Whakaari (White Island) is an active andesite-dacite volcano located on New Zealand’s northernmost continental shelf. During a series of Strombolian eruptions in 1976–2000 it produced high-Mg andesite magmas (Mg#: 65–74; SiO2: 55–58 wt. %). It has already been suggested that the production of these magmas involved complex interaction between stored and ascending magmas in a mid-crustal magma chamber that forms part of a larger trans-crustal plumbing system. Here we re-examine this proposal by employing Rhyolite-MELTS 1.2.0 and Magma Chamber Simulator to simulate liquidus relationships for one of the 1976–2000 high-Mg andesites from Whakaari (P41600). It was found that production of the main phenocryst assemblage (olivine + Cr-spinel + orthopyroxene + clinopyroxene + plagioclase + magnetite), mineral compositions, and liquid line of descent (as determined from matrix glasses) requires 30–60% fractional crystallisation at comparatively low pressures (< 100 MPa) and melt-H2O concentrations (< 2 wt. %) with moderate fO2 (from Ni-NiO to one log unit above Ni-NiO) and temperatures of 1140°C to 1000°C. At least 0.5 wt.% water is required to stabilise olivine at 60 MPa although original magmatic water concentrations may have been significantly higher. The early loss of magmatic water is a predictable consequence of both the low pressures of fractionation and the partitioning of H2O into a CO2-rich vapour phase. Polybaric crystallisation does not improve the simulations when compared to the isobaric model. Considering these observations, it is unlikely that evolution of the Whakaari high-Mg andesites involved significant fractionation within the mid- to lower-crust. However, there are aspects of magma evolution (particularly for FeOT and TiO2) that are not well modelled by any of our simulations. This may be because our model could not accurately simulate the effects of mixing between magmatic products or interaction between evolved melts and earlier crystallized mineral phases.
新西兰 Whakaari(白岛)安山岩-黑云母火山系统中的岩浆演化和储存条件
Whakaari(白岛)是一座安山岩-闪长岩活火山,位于新西兰最北端的大陆架上。在 1976-2000 年的一系列火山爆发中,它产生了高镁安山岩岩浆(镁:65-74;二氧化硅:55-58 wt.%)。已经有人提出,这些岩浆的产生涉及到构成更大的跨地壳管道系统一部分的地壳中层岩浆室中储存的岩浆和上升的岩浆之间复杂的相互作用。在此,我们采用 Rhyolite-MELTS 1.2.0 和岩浆室模拟器,模拟了 Whakaari 1976-2000 年高镁安山岩(P41600)中的一个岩浆室的液相关系,从而重新检验了这一观点。研究发现,在相对较低的压力(100 兆帕)和熔融-H2O 浓度(2 wt.%)、适度的 fO2(从 Ni-NiO 到 Ni-NiO 以上的一个对数单位)和 1140°C 至 1000°C 的温度下进行分层结晶。要使橄榄石在 60 兆帕的压力下保持稳定,至少需要 0.5 重量%的水,尽管最初的岩浆水浓度可能要高得多。岩浆水的早期流失是低压分馏和将 H2O 分入富含 CO2 的气相的可预测结果。与等压模型相比,多压结晶并没有改善模拟结果。考虑到这些观察结果,瓦卡里高镁安山岩的演化不太可能涉及中下岩壳内的重大分馏。然而,岩浆演化的某些方面(特别是铁OT和TiO2)并没有被我们的任何模拟所很好地模拟。这可能是因为我们的模型无法准确模拟岩浆产物之间的混合效应或演化熔体与早期结晶矿物相之间的相互作用。
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来源期刊
Journal of Petrology
Journal of Petrology 地学-地球化学与地球物理
CiteScore
6.90
自引率
12.80%
发文量
117
审稿时长
12 months
期刊介绍: The Journal of Petrology provides an international forum for the publication of high quality research in the broad field of igneous and metamorphic petrology and petrogenesis. Papers published cover a vast range of topics in areas such as major element, trace element and isotope geochemistry and geochronology applied to petrogenesis; experimental petrology; processes of magma generation, differentiation and emplacement; quantitative studies of rock-forming minerals and their paragenesis; regional studies of igneous and meta morphic rocks which contribute to the solution of fundamental petrological problems; theoretical modelling of petrogenetic processes.
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