2-D Versus 3-D Magnetotelluric Data Interpretation

Ledo, Juanjo

doi:10.1007/s10712-006-0002-4

Cited by 51 publications

(33 citation statements)

References 100 publications

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“…The tipper is included where available, which is most of the land stations. Caution over use of the TE mode arises over concerns of the impacts of potential 3D structure on a 2D inversion: TM mode data are less sensitive to finite strike effects (e.g., Wannamaker, 1999;Ledo, 2005). Inversions were run using the 2D inversion of Rodi and Mackie (2001) as implemented within the Winglink software package.…”

Section: Modelingmentioning

confidence: 99%

Electrical structure of the central Cascadia subduction zone: The EMSLAB Lincoln Line revisited

Evans

Wannamaker

McGary³

et al. 2014

Earth and Planetary Science Letters

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Section: Modelingmentioning

confidence: 99%

Electrical structure of the central Cascadia subduction zone: The EMSLAB Lincoln Line revisited

Evans

Wannamaker

McGary³

et al. 2014

Earth and Planetary Science Letters

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“…The result of this analysis shows that our data are mainly 3D. However, if a preferential direction can be determined, the 2D inversion of the impedance tensor determinant makes a reasonable approximation to 3D structures in many cases (Pedersen and Engels 2005;Ledo 2006), which is the case for this deltaic system. Based on the fluvio-deltaic facies distribution, transitional boundaries and main stratigraphical continuity tendencies, it can be observed that profiles PS1 and PS4 follow the actual river channel and its perpendicular direction, respectively, and therefore we have created 2D resistivity models using the determinant of the impedance tensor mode.…”

Section: Amt Methodsmentioning

confidence: 70%

“…5). This parameter is invariant under rotation and makes it suitable for qualitative interpretation (Vozoff 1972;Ledo 2006). Responses over 3D structures may show complex behaviour for individual impedancetensor elements, whereas much simpler and less distorted behavior of the determinant impedance usually can be well explained by 2D models (Pedersen and Engels 2005).…”

Section: Amt Methodsmentioning

confidence: 99%

Integrating Hydrogeological and Geophysical Methods for the Characterization of a Deltaic Aquifer System

et al. 2011

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Groundwater management needs detailed aquifer characterization, especially in semiarid costal aquifer systems that are under hydrological pressure. Our study area is in the Tordera delta, northeastern coast of Spain, where a detrital fluvio-deltaic aquifer system has been developed above granitic basement. The main purpose of this study is to characterize the complex lithological structure and the seawater intrusion state by combining hydrological information, audiomagnetotelluric (AMT) and seismic reflection and refraction models. This allowed us to provide spatially continuous information about aquifer properties and processes. Thus, we have determined the thickness and continuity of the aquifer units, as well as the morphology and depth to the basement. The models revealed that the main seawater intrusion main path is found in the western deltaic area that coincides with an existing buried paleochannel. This new result explains the anomalously high chlorine concentrations observed in the deep semiconfined aquifer more than 1,500 m inland.

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“…2-D inversions are then performed to yield 2-D cross-sectional models for profile interpretation. The dangers of 2-D inversions being influenced by 3-D structures are demonstrated with synthetic data in Siripunvaraporn et al (2005b) and Ledo (2006) and with real data in Simpson and Bahr (2005) and Newman et al (2003). All studies indicate that if the data contains 3-D structures, 2-D inversion can mislead an interpretation.…”

Section: When Is 3-d Inversion Useful? (Advantages Of 3-d Inversion Omentioning

confidence: 89%

Three-Dimensional Magnetotelluric Inversion: An Introductory Guide for Developers and Users

Siripunvaraporn

2011

Surv Geophys

115

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In the last few decades, the demand for three-dimensional (3-D) inversions for magnetotelluric data has significantly driven the progress of 3-D codes. There are currently a lot of new 3-D inversion and forward modeling codes. Some, such as the WSINV3DMT code of the author, are available to the academic community. The goal of this paper is to summarize all the important issues involving 3-D inversions. It aims to show how inversion works and how to use it properly. In this paper, I start by describing several good reasons for doing 3-D inversion instead of 2-D inversion. The main algorithms for 3-D inversion are reviewed along with some comparisons of their advantages and disadvantages. These algorithms are the classical Occam's inversion, the data space Occam's inversion, the Gauss-Newton method, the Gauss-Newton with the conjugate gradient method, the non-linear conjugate gradient method, and the quasi-Newton method. Other variants are based on these main algorithms. Forward modeling, sensitivity calculations, model covariance and its parallel implementation are all necessary components of inversions and are reviewed here. Rules of thumb for performing 3-D inversion are proposed for the benefit of the 3-D inversion novice. Problems regarding 3-D inversions are discussed along with suggested topics for future research for the developers of the next decades.

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2-D Versus 3-D Magnetotelluric Data Interpretation

Cited by 51 publications

References 100 publications

Electrical structure of the central Cascadia subduction zone: The EMSLAB Lincoln Line revisited

Electrical structure of the central Cascadia subduction zone: The EMSLAB Lincoln Line revisited

Integrating Hydrogeological and Geophysical Methods for the Characterization of a Deltaic Aquifer System

Three-Dimensional Magnetotelluric Inversion: An Introductory Guide for Developers and Users

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