Mineral precipitation-induced porosity reduction and its effect on transport parameters in diffusion-controlled porous media

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Aurélie Chagneau, Francis Claret, Frieder Enzmann, Michael Kersten, Stephanie Heck, Benoît Madé, Thorsten Schäfer
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引用次数: 44

Abstract

In geochemically perturbed systems where porewater and mineral assemblages are unequilibrated the processes of mineral precipitation and dissolution may change important transport properties such as porosity and pore diffusion coefficients. These reactions might alter the sealing capabilities of the rock by complete pore-scale precipitation (cementation) of the system or by opening new migration pathways through mineral dissolution. In actual 1D continuum reactive transport codes the coupling of transport and porosity is generally accomplished through the empirical Archie’s law. There is very little reported data on systems with changing porosity under well controlled conditions to constrain model input parameters. In this study celestite (SrSO4) was precipitated in the pore space of a compacted sand column under diffusion controlled conditions and the effect on the fluid migration properties was investigated by means of three complementary experimental approaches: (1) tritiated water (HTO) tracer through diffusion, (2) computed micro-tomography (μ-CT) imaging and (3) post-mortem analysis of the precipitate (selective dissolution, SEM/EDX).

The through-diffusion experiments reached steady state after 15?days, at which point celestite precipitation ceased and the non-reactive HTO flux became constant. The pore space in the precipitation zone remained fully connected using a 6?μm μ-CT spatial resolution with 25?% porosity reduction in the approx. 0.35?mm thick dense precipitation zone. The porosity and transport parameters prior to pore-scale precipitation were in good agreement with a porosity of 0.42?±?0.09 (HTO) and 0.40?±?0.03 (μ-CT), as was the mass of SrSO4 precipitate estimated by μ-CT at 25?±?5?mg and selective dissolution 21.7?±?0.4?mg, respectively. However, using this data as input parameters the 1D single continuum reactive transport model was not able to accurately reproduce both the celestite precipitation front and the remaining connected porosity. The model assumed there was a direct linkage of porosity to the effective diffusivity using only one cementation value over the whole porosity range of the system investigated.

The 1D single continuous model either underestimated the remaining connected porosity in the precipitation zone, or overestimated the amount of precipitate. These findings support the need to implement a modified, extended Archie’s law to the reactive transport model and show that pore-scale precipitation transforms a system (following Archie’s simple power law with only micropores present) towards a system similar to clays with micro- and nanoporosity.

Abstract Image

在扩散控制的多孔介质中,矿物沉淀诱导的孔隙减少及其对输运参数的影响
在地球化学扰动系统中,孔隙水和矿物组合不平衡,矿物沉淀和溶解过程可能改变孔隙率和孔隙扩散系数等重要输运性质。这些反应可能通过系统的完全孔隙尺度沉淀(胶结)或通过矿物溶解开辟新的迁移途径来改变岩石的密封能力。在实际的一维连续反应输运代码中,输运与孔隙度的耦合一般是通过经验阿尔奇定律来完成的。在井控条件下,由于模型输入参数的限制,孔隙度变化的系统数据很少。在扩散控制条件下,天青石(SrSO4)在压实砂柱孔隙中析出,并通过三种互补的实验方法(1)氚化水(HTO)扩散示踪,(2)微计算机断层扫描(μ-CT)成像,(3)沉淀的死后分析(选择性溶解,SEM/EDX)研究了天青石(SrSO4)对流体运移特性的影响。通过扩散实验在15?此时天青石降水停止,非反应性HTO通量趋于恒定。降水区的孔隙空间通过6?μ μ-CT空间分辨率为25?孔隙率降低约%。0.35 ?毫米厚的密集降水区。孔隙度和输运参数在孔隙度为0.42±0.09 (HTO)和0.40±0.03 (μ-CT)的情况下与孔尺度沉淀前的孔隙度和输运参数一致,μ-CT估计的SrSO4沉淀质量为25±5?Mg和选择性溶出21.7±0.4?分别毫克。然而,使用这些数据作为输入参数,一维单一连续反应输运模型无法准确再现天青石降水锋和剩余连通孔隙度。该模型假设孔隙度与有效扩散系数之间存在直接联系,仅使用在所研究体系的整个孔隙度范围内的一个胶结值。一维单连续模型要么低估了沉淀带剩余连通孔隙度,要么高估了沉淀量。这些发现支持了对反应输移模型进行修正和扩展的阿奇定律的必要性,并表明孔隙尺度的降水将一个系统(仅存在微孔时遵循阿奇简单幂定律)转变为一个类似于具有微孔和纳米孔的粘土系统。
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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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