岩浆与碳酸盐的相互作用推动了火山弧浅层岩钉和岩屑中二氧化碳的生成和金属富集

IF 4.8 1区地球科学 Q1 GEOLOGY

Geology Pub Date : 2023-12-07 DOI:10.1130/g51439.1

R.A. Morris, D. Canil, J. Spence

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引用次数: 0

摘要

地壳碳酸盐对弧岩浆中二氧化碳的贡献及其在长期碳循环中的作用一直存在争议。为了更好地了解弧岩浆中二氧化碳产生的贡献和机制，我们详细研究了加拿大温哥华岛侏罗纪富矿弧的玄武岩脉和与碳酸盐的储层接触。我们发现沿岩脉和岩基边缘形成的离散边界熔体与石灰岩接触，显示出独特的Ca, U和Sr富集，Si枯竭，87Sr/86Sr接近主石灰岩值(~ 0.708)。二元混合模拟表明，~ 20% ~ 25%的灰岩同化到玄武岩中形成边界熔体。边界和内部熔体之间的不同粘度阻碍了混合和化学均质化，但似乎促进了上坡扩散和金属富集，这些系统在几分钟到几天内冷却。虽然在弧岩浆系统中，浅岩脉和岩台的体积可能较小，但岩浆的开放流动和通道的大表面积极大地增强了岩浆-碳酸盐岩的相互作用，并最终产生二氧化碳，可能比更常见和体积更大的岩体产生的二氧化碳更大。

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Magma-carbonate interactions drive CO2 production and metal enrichment in shallow dikes and sills at volcanic arcs

The contribution of CO2 from crustal carbonates into arc magmas is debated, as is its role in the long-term C cycle. To better understand the contributions and mechanisms that drive CO2 production in arc magmas, we examined in detail basaltic dike and sill contacts with carbonate in the Jurassic Bonanza arc on Vancouver Island, Canada. We discovered discrete boundary melts that formed along dike and sill margins in contact with limestone, which display unique Ca, U, and Sr enrichments, Si depletion, and 87Sr/86Sr that approaches host limestone values (∼0.708). Binary mixing modeling indicates ∼20%−25% limestone assimilation into basalt formed the boundary melts. Contrasting viscosities between boundary and interior melts hinder mixing and chemical homogenization but appear to promote uphill diffusion and metal enrichment within systems that cool in minutes to days. While shallow dikes and sills may be volumetrically minor in an arc magma system, the open flow of magma and large surface area in channels greatly enhances magma-carbonate interactions, and ultimately CO2 production, likely over that of more common and voluminous plutons.

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来源期刊

Geology 地学-地质学

CiteScore

10.00

自引率

3.40%

发文量

228

审稿时长

6.2 months

期刊介绍： Published since 1973, Geology features rapid publication of about 23 refereed short (four-page) papers each month. Articles cover all earth-science disciplines and include new investigations and provocative topics. Professional geologists and university-level students in the earth sciences use this widely read journal to keep up with scientific research trends. The online forum section facilitates author-reader dialog. Includes color and occasional large-format illustrations on oversized loose inserts.