CO2 diffusion in dry and hydrous leucititic melt

IF 1.8 3区地球科学 Q2 MINERALOGY

European Journal of Mineralogy Pub Date : 2023-02-27 DOI:10.5194/ejm-35-117-2023

Lennart Koch, B. Schmidt

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引用次数: 0

Abstract

Abstract. Using the diffusion couple technique, diffusion of CO2 in a leucititic melt from the Colli Albani Volcanic District in Italy was investigated at temperatures between 1200 and 1350 ∘C in an internally heated pressure vessel at 300 MPa. To examine the effect of dissolved H2O in the melt, experiments were performed for a nominally dry melt (0.18 ± 0.03 wt % H2O) and for a hydrous melt containing 3.36 ± 0.28 wt % H2O. Diffusion experiments were run for 40 to 120 min and terminated by rapid quench. CO2 concentration profiles were subsequently measured via attenuated total reflection Fourier transform infrared spectroscopy (ATR-FTIR) and fitted with error functions to obtain individual diffusion coefficients. For the anhydrous and hydrous sample series, seven diffusion coefficients were determined each. Diffusivity was found to increase exponentially with temperature for both melts following an Arrhenius behaviour. The Arrhenius equation for the nominally dry leucititic melt is described by log⁡DCO2=-1.44(±0.24)⋅10000T-1.95(±1.59), where DCO2 is the diffusion coefficient in m2 s−1 and T is the temperature in K. In the experimental temperature range, H2O has an accelerating effect on CO2 diffusion. At 1200 ∘C, diffusivity increases from 1.94 × 10−12 m2 s−1 in the dry melt to 1.54 × 10−11 m2 s−1 in the hydrous melt. The Arrhenius equation for the leucititic melt containing 3.36±0.28 wt % H2O is given by log⁡DCO2=-1.09(±0.30)⋅10000T-3.41(±1.99). The activation energies for CO2 were determined to be 275 ± 47 kJ mol−1 for the anhydrous melt and 209 ± 58 kJ mol−1 for the hydrous melt. The high CO2 activation energy in the leucititic melt indicates that the diffusion might be partly attributed to the carbonate species. At high magmatic temperatures above 1200 ∘C, CO2 diffusivity in the leucititic melt is only slightly lower than CO2 diffusion in rhyolitic and basaltic melts, suggesting that CO2 diffusion in natural melts is relatively independent from the bulk melt composition at such temperatures. CO2 diffuses slower than other volatile components such as halogens and H2O in depolymerized silicate melts. Thus, a fractionation of volatiles can occur during magma ascent and degassing. The experimental data on CO2 diffusion can be used for modelling the degassing mechanisms of ultrapotassic mafic melts.

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干湿白质熔体中CO2的扩散

摘要利用扩散耦合技术，在1200到1350的温度下，研究了CO2在意大利科利-奥尔巴尼火山区亮氨酸熔体中的扩散 ∘Cin内部加热压力容器，温度为300 MPa。为了检验熔体中溶解的H2O的影响，对名义熔体（0.18 ± 0.03 wt % H2O），并且对于含有3.36的含水熔体 ± 0.28 wt % 一氧化二氢扩散实验进行了40到120次 min，并通过快速淬火终止。随后通过衰减全反射傅里叶变换红外光谱（ATR-FTIR）测量CO2浓度分布，并用误差函数拟合以获得个体扩散系数。对于无水和含水样品系列，分别测定了七个扩散系数。在阿伦尼斯行为之后，发现两种熔体的扩散率随温度呈指数级增加。名义上干燥的白榴石熔体的阿伦纽斯方程由log描述⁡DCO2=-1.44（±0.24）·10000T-1.95（±1.59），其中DCO2是 m2 s−1，T是以K为单位的温度。在实验温度范围内，H2O对CO2的扩散有加速作用。1200 ∘C、扩散率从1.94增加 × 10−12 m2 干熔体中的s−1至1.54 × 10−11 m2 含水熔体中的s−1。含3.36±0.28亮氨酸熔体的Arrhenius方程 wt % H2O由log表示⁡DCO2=-1.09（±0.30）·10000T-3.41（±1.99）。测得CO2的活化能为275 ± 47 kJ mol−1（无水熔体）和209 ± 58 kJ mol−1表示氢熔体。亮氨酸熔体中的高CO2活化能表明扩散可能部分归因于碳酸盐物种。在1200以上的高岩浆温度下 ∘C、玄武岩熔体中的CO2扩散率仅略低于流纹质玄武岩熔体中CO2的扩散率，这表明在这种温度下，天然熔体中的二氧化碳扩散相对独立于大块熔体的组成。在解聚硅酸盐熔体中，CO2的扩散速度比其他挥发性成分（如卤素和H2O）慢。因此，在岩浆上升和脱气过程中会发生挥发物的分馏。CO2扩散实验数据可用于模拟超钾镁铁质熔体的脱气机制。

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来源期刊

European Journal of Mineralogy 地学-矿物学

CiteScore

2.80

自引率

9.50%

发文量

审稿时长

6-12 weeks

期刊介绍： EJM was founded to reach a large audience on an international scale and also for achieving closer cooperation of European countries in the publication of scientific results. The founding societies have set themselves the task of publishing a journal of the highest standard open to all scientists performing mineralogical research in the widest sense of the term, all over the world. Contributions will therefore be published primarily in English. EJM publishes original papers, review articles and letters dealing with the mineralogical sciences s.l., primarily mineralogy, petrology, geochemistry, crystallography and ore deposits, but also biomineralogy, environmental, applied and technical mineralogy. Nevertheless, papers in any related field, including cultural heritage, will be considered.