Reconstruction of geologic bodies in depth associated with a sedimentary basin using gravity and magnetic data

Barbosa, Valéria C. F.; Silva, João B. C.

doi:10.1111/j.1365-2478.2011.00997.x

Cited by 33 publications

(23 citation statements)

References 85 publications

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“…This procedure is repeated over the whole data set in a moving-data window scheme. As pointed out by Barbosa and Silva (2011), this procedure has the disadvantage of computing a large number of inconsistent estimated solutions making it difficult to decide on the correct locations of the geologic sources. By assuming a null base level in equation 1, Silva and Barbosa (2003) deduce the analytical estimatorsx o ;ŷ o ; andẑ o (see equations 8-10 in Silva and Barbosa, 2003).…”

Section: Methodsmentioning

confidence: 99%

“…However, Manuscript received by the Editor 10 December 2012; revised manuscript received 9 June 2013; published online 4 October 2013. 1 this scheme leads to a large number of Euler solutions (Barbosa and Silva, 2011). This scenario is further complicated when the geometry of the source is unknown and when multiple sources with different geometries are present.…”

Section: Introductionmentioning

confidence: 98%

“…This procedure leads to a set of maps, each one displaying a broad cloud of Euler solutions, rendering nontrivial the interpretation of the locations of multiple geologic bodies. According to Barbosa and Silva (2011), the large number of estimated solutions by Euler deconvolution still remains an operational disadvantage of this method.…”

Section: Introductionmentioning

confidence: 99%

“…After the Reid et al (1990) extension, Euler deconvolution has gained enormous popularity as a semiautomated method to estimate the 3D position of magnetic sources. This popularity is because Euler deconvolution is a fast-processing method that requires no prior knowledge about the anomalous source magnetization, but just its homogeneity in intensity and direction (Barbosa and Silva, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Estimating the nature and the horizontal and vertical positions of 3D magnetic sources using Euler deconvolution

et al. 2013

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We have developed a new method that drastically reduces the number of the source location estimates in Euler deconvolution to only one per anomaly. Our method employs the analytical estimators of the base level and of the horizontal and vertical source positions in Euler deconvolution as a function of the x-and y-coordinates of the observations. By assuming any tentative structural index (defining the geometry of the sources), our method automatically locates plateaus, on the maps of the horizontal coordinate estimates, indicating consistent estimates that are very close to the true corresponding coordinates. These plateaus are located in the neighborhood of the highest values of the anomaly and show a contrasting behavior with those estimates that form inclined planes at the anomaly borders. The plateaus are automatically located on the maps of the horizontal coordinate estimates by fitting a first-degree polynomial to these estimates in a moving-window scheme spanning all estimates. The positions where the angular coefficient estimates are closest to zero identify the plateaus of the horizontal coordinate estimates. The sample means of these horizontal coordinate estimates are the best horizontal location estimates. After mapping each plateau, our method takes as the best structural index the one that yields the minimum correlation between the total-field anomaly and the estimated base level over each plateau. By using the estimated structural index for each plateau, our approach extracts the vertical coordinate estimates over the corresponding plateau. The sample means of these estimates are the best depth location estimates in our method. When applied to synthetic data, our method yielded good results if the bodies produce weak-and mid-interfering anomalies. A test on real data over intrusions in the Goiás Alkaline Province, Brazil, retrieved sphere-like sources suggesting 3D bodies.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Estimating the nature and the horizontal and vertical positions of 3D magnetic sources using Euler deconvolution

et al. 2013

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“…Typically, most of the gravity-inversion methods developed to produce the depth-to-basement estimation approximate the sedimentary pack by a set of prisms with tops that coincide with the Earths's surface, and the thicknesses of the prisms represent the basement depths and are the parameters to be estimated. The study by Barbosa and Silva (2011) provides additional details about the methods used to recover the basement relief. Generally, these methods that discretize the basin into a set of prisms can be grouped into two categories.…”

Section: Introductionmentioning

confidence: 99%

Regularization parameter selection in the 3D gravity inversion of the basement relief using GCV: A parallel approach

Mojica¹,

Bassrei²

2015

Computers & Geosciences

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3D joint interpretation of potential field, geology, and well data to evaluate a salt dome in the Qarah‐Aghaje area, Zanjan, NW Iran

Ghari

Varfinezhad

Parnow

2023

Near Surface Geophysics

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As geophysical parameters are not always functionally related, treating multiple geophysical data sets to have a realistic geological model is not straightforward. An effective strategy to derive a geological interpretation is a combination of several geophysical methods with geological and well observations, each with its advantages and limitations. Gravity and magnetic methods are encouraging tools to investigate salt domes due to enough density and susceptibility contrasts between salt minerals and the background sedimentary rocks. In this paper, the dome-shaped salt unit in the Qarah-Aghaje area in Zanjan, located in the northwestern part of Iran, is investigated through the integration of 3D inversion models obtained from gravity and magnetic data and geological and well information. The 3D inversion of both data sets is made using a weighted damped minimum length solution for which model weighting is constructed from multiplying depth weighting and compactness constraints. At first, a synthetic case with a high degree of similarity to the real case is considered to evaluate the efficiency of the adopted inverse algorithm. Then, the inversion algorithm is implemented on the collected gravity and magnetic methods, and interpretation is made utilizing 3D obtained inverse models and geologic and well data. The result shows a dome-shaped potash-bearing salt unit that starts from a depth of 12 m and continues to the depth of 200 m. The drilled well in the centre of the main source of the salt (Well 3) demonstrates a depth range of 11-115 m.

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Reconstruction of geologic bodies in depth associated with a sedimentary basin using gravity and magnetic data

Cited by 33 publications

References 85 publications

Estimating the nature and the horizontal and vertical positions of 3D magnetic sources using Euler deconvolution

Estimating the nature and the horizontal and vertical positions of 3D magnetic sources using Euler deconvolution

Regularization parameter selection in the 3D gravity inversion of the basement relief using GCV: A parallel approach

3D joint interpretation of potential field, geology, and well data to evaluate a salt dome in the Qarah‐Aghaje area, Zanjan, NW Iran

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