Rehydrated glass embayments record the cooling of a Yellowstone ignimbrite

Geology Pub Date : 2024-03-26 DOI:10.1130/g51905.1
K. Befus, James O. Thompson, Chelsea M. Allison, A. Ruefer, Michael Manga
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Abstract

Hydration fronts penetrate 50−135 μm into glassy rhyolite embayments hosted in quartz crystals from the Mesa Falls Tuff in the Yellowstone Plateau volcanic field. The hydration fronts occur as steep enrichments that reach 2.4 ± 0.6 wt% H2O at the embayment opening, representing much higher values than interior concentrations of 0.9 ± 0.2 wt% H2O. Molecular water accounts for most of the water enrichment. Water speciation indicates the hydration fronts comprise absorbed meteoric water that modified the original magmatic composition of the rhyolitic glass. We used finite difference diffusion models to demonstrate that glass rehydration was likely produced over a few decades as the ignimbrite cooled. Such temperatures and time scales are consistent with rare firsthand observations of decadal hydrothermal systems associated with cooling ignimbrites at Mount Pinatubo (Philippines) and the Valley of Ten Thousand Smokes (Alaska).
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再水化的玻璃嵌入物记录了黄石燃爆岩的冷却过程
水合锋面深入黄石高原火山区梅萨瀑布凝灰岩石英晶体中的玻璃质流纹岩栓塞 50-135 μm。水合锋面以陡峭的富集形式出现,在栓塞开口处达到 2.4 ± 0.6 wt% H2O,远高于内部 0.9 ± 0.2 wt% H2O 的浓度值。分子水占水富集的大部分。水的种类表明,水合锋面包括吸收的陨石水,这些水改变了流纹岩玻璃的原始岩浆成分。我们利用有限差分扩散模型证明,玻璃的再水化很可能是在流纹岩冷却的几十年间产生的。这样的温度和时间尺度与在皮纳图博火山(菲律宾)和万烟谷(阿拉斯加)罕见的与冷却流纹岩相关的十年热液系统的第一手观测结果是一致的。
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