2-D Versus 3-D Magnetotelluric Data Interpretation

Ledo, Juanjo

doi:10.1007/s10712-005-1757-8

Cited by 103 publications

(50 citation statements)

References 96 publications

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“…Jones (1983), Wanamaker et al (1984), Berdichevsky et al (1998), Park & Mackie (2000), Ledo et al (2002) and Ledo (2005) studied the limitations of 2-D interpretation of 3-D MT data and made various recommendations, showing some situations where 2-D inversion of 3-D data can properly reproduce the geoelectrical subsurface when the content in the 2-D modes is appropriately chosen for inversion. Siripunvaraporn et al (2005b) suggest that if the data are 3-D in nature but collected along a profile rather than on a grid, the results from the 3-D inversion of the MT profile are superior to the results obtained by performing 2-D inversion of the same data, even with the far coarser mesh employed in 3-D as compared to 2-D inversion.…”

mentioning

confidence: 99%

The advantages of complementing MT profiles in 3-D environments with geomagnetic transfer function and interstation horizontal magnetic transfer function data: results from a synthetic case study

Campanyà¹,

Ogaya²,

Jones³

et al. 2016

Geophys. J. Int.

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: The advantages of complementing MT profiles in 3-D environments with geomagnetic transfer function and interstation horizontal magnetic transfer function data: results from a synthetic case study. -Geophysical Journal International, 207, 3, pp. 1818-1836 S U M M A R YAs a consequence of measuring time variations of the electric and the magnetic field, which are related to current flow and charge distribution, magnetotelluric (MT) data in 2-D and 3-D environments are not only sensitive to the geoelectrical structures below the measuring points but also to any lateral anomalies surrounding the acquisition site. This behaviour complicates the characterization of the electrical resistivity distribution of the subsurface, particularly in complex areas. In this manuscript we assess the main advantages of complementing the standard MT impedance tensor (Z) data with interstation horizontal magnetic tensor (H) and geomagnetic transfer function (T) data in constraining the subsurface in a 3-D environment beneath a MT profile. Our analysis was performed using synthetic responses with added normally distributed and scattered random noise. The sensitivity of each type of data to different resistivity anomalies was evaluated, showing that the degree to which each site and each period is affected by the same anomaly depends on the type of data. A dimensionality analysis, using Z, H and T data, identified the presence of the 3-D anomalies close to the profile, suggesting a 3-D approach for recovering the electrical resistivity values of the subsurface. Finally, the capacity for recovering the geoelectrical structures of the subsurface was evaluated by performing joint inversion using different data combinations, quantifying the differences between the true synthetic model and the models from inversion process. Four main improvements were observed when performing joint inversion of Z, H and T data: (1) superior precision and accuracy at characterizing the electrical resistivity values of the anomalies below and outside the profile; (2) the potential to recover high electrical resistivity anomalies that are poorly recovered using Z data alone; (3) improvement in the characterization of the bottom and lateral boundaries of the anomalies with low electrical resistivity; and (4) superior imaging of the horizontal continuity of structures with low electrical resistivity. These advantages offer new opportunities for the MT method by making the results from a MT profile in a 3-D environment more convincing, supporting the possibility of high-resolution studies in 3-D areas without expending a large amount of economical and computational resources, and also offering better resolution of targets with high electrical resistivity.

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confidence: 99%

The advantages of complementing MT profiles in 3-D environments with geomagnetic transfer function and interstation horizontal magnetic transfer function data: results from a synthetic case study

Campanyà¹,

Ogaya²,

Jones³

et al. 2016

Geophys. J. Int.

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“…Our MT survey line was aligned perpendicular to a subsection of the PACA structure that is supposed to be much longer than it is wide, and relatively distant from its borders. Several numerical modeling studies [e.g., Wannamaker et al, 1984;Ledo, 2005] suggest that the response for a centrally located profile across an elongated 3-D body agrees with the TM response of a 2-D body with an identical cross-section, whereas the observed TE response and the vertical magnetic field are greatly depressed in comparison with the calculated 2-D model responses. Thus, to avoid spurious 3-D features on the 2-D resistivity-depth model, we have used the TM mode in the inversion to determine only the lateral extension and top of the conductive structure.…”

Section: Resistivity Model From Mt Inversionmentioning

confidence: 69%

Paraguay‐Araguaia Belt Conductivity Anomaly: A fundamental tectonic boundary in South American Platform imaged by electromagnetic induction surveys

Bologna

Padilha

Pádua

et al. 2014

Geochem Geophys Geosyst

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[1] We discovered and mapped a 1200 km-long zone of enhanced electrical conductivity through a large array of magnetometers, over a narrow corridor parallel to the Paraguay and Araguaia belts which surround the Amazon craton. The anomaly has been further studied using magnetotelluric measurements made along a 300 km profile crossing the Paraguay belt; modeling shows the anomaly at this location as a very strong 100 km-wide upper-crust to mid-crust conductor, located under a region where surficial rocks show an increase in deformation and metamorphism within the belt. From the high conductivity of the anomalous structure, its observed geometry and surface rock exposures, the most likely interpretation of its source is graphitized biogenic material in metasediments, now deeply underthrust in a Neoproterozoic or Early Cambrian suture zone. This result strongly supports the hypothesis that the collision between the Amazon plate and the western Paran a block has probably closed an ocean in the Paraguay belt region, contrary to former propositions of an ensialic evolution for this belt. Although the precise age of this ocean closure have been a matter of debate, our finding significantly constrains the tectonic setting of West Gondwana amalgamation involving the Amazon plate and its surrounding blocks.

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“…Moreover, sometimes it is possible to interpret 3D MT data as 2D (see, for instance, [26] and [27]). Traditional inversion techniques usually select one fixed dimension (the full 2D (or 3D) problem) for both, the forward simulations and the inversion.…”

Section: Dimensionally Adaptive Inversionmentioning

confidence: 99%

“…Then, we solve a higher dimensional IP by employing the information of lower dimensional IPs. This idea relies upon the results obtained in [26] and [27], where authors show that measurements often exhibit a dimensionality signature that can be properly exploited when solving IPs.…”

Section: Introductionmentioning

confidence: 99%

Dimensionally adaptive hp-finite element simulation and inversion of 2D magnetotelluric measurements

Álvarez-Aramberri

Pardo

2017

Journal of Computational Science

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2-D Versus 3-D Magnetotelluric Data Interpretation

Cited by 103 publications

References 96 publications

The advantages of complementing MT profiles in 3-D environments with geomagnetic transfer function and interstation horizontal magnetic transfer function data: results from a synthetic case study

The advantages of complementing MT profiles in 3-D environments with geomagnetic transfer function and interstation horizontal magnetic transfer function data: results from a synthetic case study

Paraguay‐Araguaia Belt Conductivity Anomaly: A fundamental tectonic boundary in South American Platform imaged by electromagnetic induction surveys

Dimensionally adaptive hp-finite element simulation and inversion of 2D magnetotelluric measurements

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