Zeolitization of a devitrified high-silica rhyolitic tuff producing dachiardite: A comparison of hydrothermal experiments with the corresponding reaction progress modeling

IF 3.1 3区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Kevin G. Knauss , Giuseppe D. Saldi , Nicolas F. Spycher
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引用次数: 0

Abstract

We have investigated the hydrothermal alteration of polished wafers of tuff reacted with dilute groundwater at 90 °C, 150 °C and 250 °C for time periods ranging from 2 months to nearly 1 year. The polished rock wafer provided a convenient surface upon which to grow secondary minerals. Reaction product minerals were identified and analyzed at the end of each experiment and, along with the evolving fluid chemistry, were compared to computational results from corresponding reaction progress models.

At 250 °C after a few months the run products in the experiment were dominantly the mordenite group zeolite minerals: dachiardite (a Ca-rich variety) and mordenite, itself. At 150 °C after a few months of reaction only minor amounts of clay were produced, but after 1 year of reaction at this temperature both mordenite group zeolites were again present. At this lower temperature the total amount of run products was much smaller. At 90 °C no run products could be seen at all, even after 1 year of reaction. The reaction progress modeling results for reaction products were in good relative agreement with the experimental results.

The higher the temperature, and the greater the extent of reaction, the better the fluid phase modeling results agreed with the actual experimental results. At 250 °C the agreement was good for nearly all elements. At 150 °C agreement for pH, SiO2, Na and K were good, but less good for Al, Mg and Ca, especially after short reaction times. At 90 °C agreement for pH, SiO2 and Na was reasonable, but not as good for the other elements, and all modeling results for short reaction times did not match experimental results as well as the longer time results.

This study demonstrates that reaction progress modeling provides a powerful tool for predicting hydrothermal rock-water interactions, with results expected to improve, as more and better quality thermodynamic and kinetic data become available and as process-oriented simulators incorporate better and more comprehensive sub-models for mineral dissolution and growth.

反硝化高硅流纹岩凝灰岩的沸石作用:水热实验与相应反应过程模拟的比较
我们研究了凝灰岩抛光晶圆与稀地下水在90°C, 150°C和250°C下反应的热液蚀变,时间范围从2个月到近1年。抛光的岩石薄片为生长次生矿物提供了方便的表面。在每次实验结束时,对反应产物矿物进行识别和分析,并与相应反应过程模型的计算结果进行比较。在250°C下加热几个月后,实验中的主要产物是丝光沸石矿物:dachiardite(一种富钙品种)和丝光沸石本身。在150℃下,经过几个月的反应,只产生了少量的粘土,但在这个温度下反应1年后,两种丝光沸石组的沸石又出现了。在这个较低的温度下,总生成量要小得多。在90°C下,即使经过1年的反应,也看不到任何运行产物。反应产物的反应过程模拟结果与实验结果相对吻合较好。温度越高,反应程度越大,流体相模拟结果与实际实验结果吻合越好。在250°C时,该协议对几乎所有元素都有效。在150℃下,SiO2、Na和K的pH一致性较好,而Al、Mg和Ca的一致性较差,特别是在较短的反应时间后。在90°C时,SiO2和Na的pH值一致性较好,但其他元素的一致性较差,并且所有短反应时间的建模结果与实验结果以及较长时间的结果都不匹配。这项研究表明,反应过程建模为预测热液岩石-水相互作用提供了一个强大的工具,随着越来越多、质量越来越高的热力学和动力学数据的出现,以及面向过程的模拟器纳入了更好、更全面的矿物溶解和生长子模型,结果有望得到改善。
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来源期刊
Applied Geochemistry
Applied Geochemistry 地学-地球化学与地球物理
CiteScore
6.10
自引率
8.80%
发文量
272
审稿时长
65 days
期刊介绍: Applied Geochemistry is an international journal devoted to publication of original research papers, rapid research communications and selected review papers in geochemistry and urban geochemistry which have some practical application to an aspect of human endeavour, such as the preservation of the environment, health, waste disposal and the search for resources. Papers on applications of inorganic, organic and isotope geochemistry and geochemical processes are therefore welcome provided they meet the main criterion. Spatial and temporal monitoring case studies are only of interest to our international readership if they present new ideas of broad application. Topics covered include: (1) Environmental geochemistry (including natural and anthropogenic aspects, and protection and remediation strategies); (2) Hydrogeochemistry (surface and groundwater); (3) Medical (urban) geochemistry; (4) The search for energy resources (in particular unconventional oil and gas or emerging metal resources); (5) Energy exploitation (in particular geothermal energy and CCS); (6) Upgrading of energy and mineral resources where there is a direct geochemical application; and (7) Waste disposal, including nuclear waste disposal.
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