大陆洪泛玄武岩中co2矿物储存的潜力——PHREEQC批式和一维扩散反应模拟

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemical Transactions Pub Date : 2012-06-14 DOI:10.1186/1467-4866-13-5
Thi Hai Van Pham, Per Aagaard, Helge Hellevang
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引用次数: 53

摘要

大陆洪水玄武岩(CFB)由于其高反应活性和丰富的二价金属离子,可以在地质时间尺度上潜在地捕获碳,被认为是潜在的二氧化碳储存场所。此外,在距离主要CO2点排放源合理距离的范围内,世界上许多地方都发现了横向广泛的CFB。根据哥伦比亚河玄武岩(CRB)的矿物和玻璃组成,估计了CFB在次生碳酸盐岩中储存CO2的潜力。我们使用原生玄武岩矿物(辉石、长石和玻璃)的动力学依赖溶解和次生相(风化产物)的局部平衡假设来模拟该系统。模拟分为封闭系统批量模拟,CO2压力恒定为100?通过对温度和反应表面积的敏感性研究,对H2O在scCO2中的反应性进行了评估,最后进行了1D反应扩散模拟,给出了CO2压力从0到100 bar的反应性。虽然反应表面积和相应的反应速率的不确定性很大,但我们已经估计了CO2矿物储存的潜力,并确定了控制碳酸化最大程度的因素。模拟表明,玄武岩在40?C可能仅限于菱铁矿和可能的镁碳酸盐的形成。钙大部分被沸石和氧化物消耗,而不是形成碳酸盐。在较高的温度下(60 - 100℃),菱镁矿建议与菱铁矿和铁白云石一起形成。作为固体碳酸盐储存的CO2的最大潜力,如果无限制地向反应提供CO2,则取决于孔隙空间的可用性,因为水化和碳酸化反应增加了固体体积并堵塞了孔隙空间。对于具有有限水量的体系,例如在scCO2相中,总碳酸化潜力受到玄武岩水化的水量的限制。
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On the potential for CO2mineral storage in continental flood basalts – PHREEQC batch- and 1D diffusion–reaction simulations

Continental flood basalts (CFB) are considered as potential CO2 storage sites because of their high reactivity and abundant divalent metal ions that can potentially trap carbon for geological timescales. Moreover, laterally extensive CFB are found in many place in the world within reasonable distances from major CO2 point emission sources.

Based on the mineral and glass composition of the Columbia River Basalt (CRB) we estimated the potential of CFB to store CO2 in secondary carbonates. We simulated the system using kinetic dependent dissolution of primary basalt-minerals (pyroxene, feldspar and glass) and the local equilibrium assumption for secondary phases (weathering products). The simulations were divided into closed-system batch simulations at a constant CO2 pressure of 100?bar with sensitivity studies of temperature and reactive surface area, an evaluation of the reactivity of H2O in scCO2, and finally 1D reactive diffusion simulations giving reactivity at CO2 pressures varying from 0 to 100?bar.

Although the uncertainty in reactive surface area and corresponding reaction rates are large, we have estimated the potential for CO2 mineral storage and identified factors that control the maximum extent of carbonation. The simulations showed that formation of carbonates from basalt at 40?C may be limited to the formation of siderite and possibly FeMg carbonates. Calcium was largely consumed by zeolite and oxide instead of forming carbonates. At higher temperatures (60 – 100?C), magnesite is suggested to form together with siderite and ankerite. The maximum potential of CO2 stored as solid carbonates, if CO2 is supplied to the reactions unlimited, is shown to depend on the availability of pore space as the hydration and carbonation reactions increase the solid volume and clog the pore space. For systems such as in the scCO2 phase with limited amount of water, the total carbonation potential is limited by the amount of water present for hydration of basalt.

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来源期刊
Geochemical Transactions
Geochemical Transactions 地学-地球化学与地球物理
CiteScore
3.70
自引率
4.30%
发文量
2
审稿时长
>12 weeks
期刊介绍: Geochemical Transactions publishes high-quality research in all areas of chemistry as it relates to materials and processes occurring in terrestrial and extraterrestrial systems.
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