Frontiers | Meshfree modelling of magnetotelluric and controlled-source electromagnetic data for conductive earth models with complex geometries

IF 2 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Jianbo Long
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引用次数: 0

Abstract

Geophysical electromagnetic survey methods are particularly effective in locating conductive mineral deposits or mineralization zones in a mineral resource exploration. The forward modelling of the electromagnetic responses over such targets is a fundamental task in quantitatively interpreting the geophysical data into a geological model. Due to the ubiquitous irregular and complex geometries associated with the mineral rock units, it is critical that the numerical modelling approach being used is able to adequately and efficiently incorporate any necessary geometries of the Earth model. To circumvent the difficulties in representing complex but necessary geometry features in an Earth model for the existing mesh-based numerical modelling approaches (e.g., finite element and finite difference methods), I present a meshfree modelling approach that does not require a mesh to solve the Maxwell’s equations. The meshfree approach utilizes a set of unconnected points to represent any geometries in the Earth model, allowing for the maximal flexibility to account for irregular surface geometries and topography. In each meshfree subdomain, radial basis functions are used to construct meshfree function approximation in transforming the differential equations in the modelling problem into linear systems of equations. The method solves the potential function equations of the Maxwell’s equations in the modelling. The modelling accuracy using the meshfree method is examined and verified using one magnetotelluric model and two frequency-domain controlled-source models. The magnetotelluric model is the well-known Dublin Test Model 2 in which the spherical geometry of the conductor in the shallow subsurface may pose as a challenge for many numerical modelling methods. The first controlled-source model is a simple half-space model with the electric dipole source for which analytical solutions exist for the modelling responses. The second controlled-source model is the volcanic massive sulphide mineral deposit from Voisey’s Bay, Labrador, Canada in which the deposit’s surface is highly irregular. For all modellings, the calculated electromagnetic responses are found to agree with other independent numerical solutions and the analytical solutions. The advantages of the meshfree method in discretizing the Earth models with complex geometries in the forward modelling of geophysical electromagnetic data is clearly demonstrated.
前沿 | 为具有复杂几何形状的导电地球模型建立磁电和可控源电磁数据的无网格模型
在矿产资源勘探中,地球物理电磁勘测方法对于定位导电矿床或成矿带尤为有效。对此类目标的电磁响应进行前向建模是将地球物理数据定量解释为地质模型的一项基本任务。由于与矿物岩石单元相关的不规则和复杂几何形状无处不在,因此所使用的数值建模方法必须能够充分有效地纳入地球模型的任何必要几何形状。为了规避现有基于网格的数值建模方法(如有限元和有限差分方法)在表示地球模型中复杂但必要的几何特征时遇到的困难,我提出了一种无网格建模方法,它不需要网格来求解麦克斯韦方程。无网格方法利用一组无连接的点来表示地球模型中的任何几何形状,允许最大限度地灵活考虑不规则的表面几何形状和地形。在每个无网格子域中,使用径向基函数构建无网格函数近似,将建模问题中的微分方程转换为线性方程组。该方法解决了建模中麦克斯韦方程的势函数方程。使用无网格方法的建模精度通过一个磁小耳模型和两个频域受控源模型进行了检验和验证。磁突触模型是著名的都柏林试验模型 2,其中浅层地下导体的球形几何形状可能对许多数值建模方法构成挑战。第一个受控源模型是一个带有电偶极源的简单半空间模型,其建模响应存在解析解。第二个受控源模型是加拿大拉布拉多 Voisey's Bay 的火山块状硫化物矿床,矿床表面极不规则。对于所有模型,计算得出的电磁响应与其他独立数值解和分析解一致。在地球物理电磁数据的前向建模中,无网格方法在离散复杂几何形状的地球模型方面的优势得到了清楚的证明。
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来源期刊
Frontiers in Earth Science
Frontiers in Earth Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
3.50
自引率
10.30%
发文量
2076
审稿时长
12 weeks
期刊介绍: Frontiers in Earth Science is an open-access journal that aims to bring together and publish on a single platform the best research dedicated to our planet. This platform hosts the rapidly growing and continuously expanding domains in Earth Science, involving the lithosphere (including the geosciences spectrum), the hydrosphere (including marine geosciences and hydrology, complementing the existing Frontiers journal on Marine Science) and the atmosphere (including meteorology and climatology). As such, Frontiers in Earth Science focuses on the countless processes operating within and among the major spheres constituting our planet. In turn, the understanding of these processes provides the theoretical background to better use the available resources and to face the major environmental challenges (including earthquakes, tsunamis, eruptions, floods, landslides, climate changes, extreme meteorological events): this is where interdependent processes meet, requiring a holistic view to better live on and with our planet. The journal welcomes outstanding contributions in any domain of Earth Science. The open-access model developed by Frontiers offers a fast, efficient, timely and dynamic alternative to traditional publication formats. The journal has 20 specialty sections at the first tier, each acting as an independent journal with a full editorial board. The traditional peer-review process is adapted to guarantee fairness and efficiency using a thorough paperless process, with real-time author-reviewer-editor interactions, collaborative reviewer mandates to maximize quality, and reviewer disclosure after article acceptance. While maintaining a rigorous peer-review, this system allows for a process whereby accepted articles are published online on average 90 days after submission. General Commentary articles as well as Book Reviews in Frontiers in Earth Science are only accepted upon invitation.
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