Modelling the Influence of Erosive Fluidization on the Morphology of Fluid Flow and Escape Structures

IF 2.8 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Mathematical Geosciences Pub Date : 2023-07-25 DOI:10.1007/s11004-023-10071-z
Shubhangi Gupta, Aaron Micallef
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Abstract

Focused fluid flow through sub-seafloor pipes and chimneys, and their seafloor manifestations as pockmarks, are ubiquitous. However, the dynamics of flow localization and evolution of fluid escape structures remain poorly understood. Models based on geomechanical mechanisms like hydro-fracturing and porosity wave propagation offer some useful insights into fluid flow and escape dynamics, but face limitations in capturing features like mobilized granular matter, especially in the upper sediment layers where the link between fracture and pockmark is not always clear. Here, we propose a mathematical model based on the multiphase theory of porous media, where changes in subsurface and seafloor morphology are resolved through seepage-induced erosion, fluidization, transport, and re-deposition of granular material. Through simulation of an idealized scenario of gas escape from overpressured shallow gas reservoir, we demonstrate that our model can capture flow localization and formation of pipes, chimneys, and pockmarks. Our simulations show (1) formation of conical focused-flow conduits with a brecciated core and annular gas channels; (2) pockmarks of W and ring shapes; and (3) pulsed release of gas. Sediment erodibility and flow anisotropy control the morphology of focused fluid flow and escape structures, while permeability shows negligible impact. While the geological setting for this study is theoretical, we show that our results have real-world analogs.

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侵蚀流化对流体流动形态和逃逸结构影响的模拟
聚焦流体通过海底管道和烟囱流动,其海底表现为麻子,是普遍存在的。然而,流体逃逸结构的流动局部化和演化动力学仍然知之甚少。基于地质力学机制(如水力压裂和孔隙波传播)的模型为流体流动和逃逸动力学提供了一些有用的见解,但在捕捉移动颗粒物质等特征方面存在局限性,特别是在上部沉积层中,裂缝和麻坑之间的联系并不总是很清楚。在这里,我们提出了一个基于多孔介质多相理论的数学模型,其中地下和海底形态的变化是通过渗透引起的侵蚀、流化、运输和颗粒物质的再沉积来解决的。通过模拟超压浅层气藏气体逸出的理想场景,我们证明了我们的模型可以捕捉流动局部化和管道、烟囱和坑穴的形成。模拟结果表明:(1)形成了带角化岩心的锥形聚焦流管道和环形气通道;(2) W形和环状麻点;(3)脉冲释放气体。沉积物的可蚀性和流动各向异性控制了聚焦流体流动和逸出结构的形态,而渗透率的影响可以忽略不计。虽然这项研究的地质背景是理论上的,但我们表明,我们的结果与现实世界相似。
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来源期刊
Mathematical Geosciences
Mathematical Geosciences 地学-地球科学综合
CiteScore
5.30
自引率
15.40%
发文量
50
审稿时长
>12 weeks
期刊介绍: Mathematical Geosciences (formerly Mathematical Geology) publishes original, high-quality, interdisciplinary papers in geomathematics focusing on quantitative methods and studies of the Earth, its natural resources and the environment. This international publication is the official journal of the IAMG. Mathematical Geosciences is an essential reference for researchers and practitioners of geomathematics who develop and apply quantitative models to earth science and geo-engineering problems.
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