Modeling liquid transport in the Earth's mantle as two-phase flow: effect of an enforced positive porosity on liquid flow and mass conservation

IF 3.2 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Solid Earth Pub Date : 2024-01-17 DOI:10.5194/se-15-23-2024
Changyeol Lee, Nestor G. Cerpa, Dongwoo Han, Ikuko Wada
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Abstract

Abstract. Fluid and melt transport in the solid mantle can be modeled as a two-phase flow in which the liquid flow is resisted by the compaction of the viscously deforming solid mantle. Given the wide impact of liquid transport on the geodynamical and geochemical evolution of the Earth, the so-called “compaction equations” are increasingly being incorporated into geodynamical modeling studies. When implementing these equations, it is common to use a regularization technique to handle the porosity singularity in the dry mantle. Moreover, it is also common to enforce a positive porosity (liquid fraction) to avoid unphysical negative values of porosity. However, the effects of this “capped” porosity on the liquid flow and mass conservation have not been quantitatively evaluated. Here, we investigate these effects using a series of 1- and 2-dimensional numerical models implemented using the commercial finite-element package COMSOL Multiphysics®. The results of benchmarking experiments against a semi-analytical solution for 1- and 2-D solitary waves illustrate the successful implementation of the compaction equations. We show that the solutions are accurate when the element size is smaller than half of the compaction length. Furthermore, in time-evolving experiments where the solid is stationary (immobile), we show that the mass balance errors are similarly low for both the capped and uncapped (i.e., allowing negative porosity) experiments. When Couette flow, convective flow, or subduction corner flow of the solid mantle is assumed, the capped porosity leads to overestimations of the mass of liquid in the model domain and the mass flux of liquid across the model boundaries, resulting in intrinsic errors in mass conservation even if a high mesh resolution is used. Despite the errors in mass balance, however, the distributions of the positive porosity and peaks (largest positive liquid fractions) in both the uncapped and capped experiments are similar. Hence, the capping of porosity in the compaction equations can be reasonably used to assess the main pathways and first-order distribution of fluids and melts in the mantle.
将地幔中的液体传输模拟为两相流动:强制正孔隙度对液体流动和质量守恒的影响
摘要。固体地幔中的流体和熔体运移可被模拟为两相流动,其中液体流动受到粘性变形固体地幔的压实阻力。鉴于液体输运对地球地球动力学和地球化学演化的广泛影响,所谓的 "压实方程 "正越来越多地被纳入地球动力学建模研究。在实施这些方程时,通常使用正则化技术来处理干地幔中的孔隙率奇异性。此外,为了避免出现不符合物理的负孔隙度值,通常还强制执行正孔隙度(液体分数)。然而,这种 "封顶 "孔隙度对液体流动和质量守恒的影响尚未得到定量评估。在此,我们使用商用有限元软件包 COMSOL Multiphysics® 建立了一系列一维和二维数值模型,对这些影响进行了研究。针对一维和二维孤波的半解析解的基准实验结果表明了压实方程的成功实施。我们发现,当元素尺寸小于压实长度的一半时,解法是准确的。此外,在固体静止(不移动)的时间演化实验中,我们表明,有封盖和无封盖(即允许负孔隙率)实验的质量平衡误差同样很低。当假定固体地幔的库瓦特流、对流或俯冲角流时,封顶孔隙度会导致高估模型域中的液体质量和模型边界的液体质量通量,从而导致质量守恒的内在误差,即使使用高网格分辨率也是如此。尽管存在质量平衡误差,但未封顶实验和封顶实验中的正孔隙度和峰值(最大正液体分数)分布是相似的。因此,压实方程中的孔隙度封顶可以合理地用于评估地幔中流体和熔体的主要路径和一阶分布。
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来源期刊
Solid Earth
Solid Earth GEOCHEMISTRY & GEOPHYSICS-
CiteScore
6.90
自引率
8.80%
发文量
78
审稿时长
4.5 months
期刊介绍: Solid Earth (SE) is a not-for-profit journal that publishes multidisciplinary research on the composition, structure, dynamics of the Earth from the surface to the deep interior at all spatial and temporal scales. The journal invites contributions encompassing observational, experimental, and theoretical investigations in the form of short communications, research articles, method articles, review articles, and discussion and commentaries on all aspects of the solid Earth (for details see manuscript types). Being interdisciplinary in scope, SE covers the following disciplines: geochemistry, mineralogy, petrology, volcanology; geodesy and gravity; geodynamics: numerical and analogue modeling of geoprocesses; geoelectrics and electromagnetics; geomagnetism; geomorphology, morphotectonics, and paleoseismology; rock physics; seismics and seismology; critical zone science (Earth''s permeable near-surface layer); stratigraphy, sedimentology, and palaeontology; rock deformation, structural geology, and tectonics.
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