Moho depths for Antarctica Region by the inversion of ground-based gravity data

Borghi, Alessandra

doi:10.1093/gji/ggac249

Cited by 5 publications

(3 citation statements)

References 41 publications

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“…Gravity data are widely used for earth sciences research. The majority of these studies are carried out with either ground-based (terrestrial) gravity data (Borghi 2022; Ardestani and Mousavi 2023), or satellite gravity data (Chouhan et al 2019; Sahoo and Pal 2021; Kumar et al 2022). Terrestrial gravity data, unlike satellite gravity models, have a great advantage in terms of accuracy on short wavelength information.…”

Section: Introductionmentioning

confidence: 99%

High precision structural mapping using advanced gravity processing methods: a case study from the North region of Cameroon

Kamto,

Oksum,

Yap

et al. 2023

Acta Geophys.

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The main purpose of this work is to perform a high-precision mapping of geological features (lineaments and faults) likely to develop underground aquifers in the crystalline and metamorphic rocks of northern Cameroon. The main techniques used for gravity data processing included the tilt angle of horizontal gradient (TAHG), the improved logistic lter (ILF), the fast sigmoid edge detector lter (FSF), and an edge detection lter based on the arcsine function (ASF). Before applying these edge detection lters to major geological units of North Cameroon, their effectiveness and performance have been assessed through synthetic gravity data with and without gravity perturbation. In addition, the Euler deconvolution formula has been used to estimate the position and the apparent depth of anomalous gravity sources in the study region. It appears that the main structural features are trending along the N-S, NNE-SSW and NE-SW directions. The deepest density anomalies in the region are identi ed in the NW-SE direction, which coincides well with the extension of the West and Central African rift system in the study area. The advanced edge detection techniques and the Euler deconvolution method have both identi ed a network of super cial lineaments around longitude 13 o N and latitude 8 o N, and located between 0 and 4 km depth. The NW-SE trending crustal features outlined in the northeast of the region, indicate that the area would have been the target of a uniform tectonic activity. This work is a contribution to a better knowledge of the con guration of fractures network, and to a better exploitation of groundwater resources available in the region.

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Section: Introductionmentioning

confidence: 99%

High precision structural mapping using advanced gravity processing methods: a case study from the North region of Cameroon

Kamto,

Oksum,

Yap

et al. 2023

Acta Geophys.

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“…Harash et al and Liu et al apply the gravity inversion to obtain the Moho topography. For the Moho inversion from gravity anomalies, the Parker-Oldenburg methods in Fourier domain are powerful tools (Zhang et al, 2020;Elmas and Karsl, 2021;Borghi, 2022). The other contributions in this Research Topic are focusing on the subsurface density structures modeling using gravity anomalies (Nigussie et al; Nigussie et al; Moura and Marangoni; Pánisová et al).…”

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confidence: 99%

Editorial: Applications of gravity anomalies in geophysics

Zhang,

Greco,

Sacek

et al. 2024

Front. Earth Sci.

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Editorial on the Research Topic Applications of gravity anomalies in geophysicsWith the progress of cheap, lightweight, and efficient gravimeters (Carbone et al., 2020;Stray et al., 2022;Kim and Choi, 2023), gravity anomalies are expected to receive wider attention in the future, opening up new perspectives for increasing the capability of gravimetry to Earth sciences. Since the knowledge of the crustal density of a planet is important in determining its interior structure, gravity anomaly is widely used in Solid Earth and exploration geophysics, and also extended to the moon and Mars. In addition to the routine applications focusing on the crustal density structure, contributing to the characterization and definition of underground structures at various scales, time-varying gravity, microgravity survey, and gravity admittance are widely applied in order to supply unique information on the dynamics of underground processes. The goal of this Research Topic is to highlight the various extracted information from gravity anomalies in applications, toward an understanding of choosing appropriate methods dealing with gravity anomalies in varying study cases.There are ten accepted papers on this Research Topic focusing on the following four research questions.The first question is about the equivalent-layer technique (Oliveira Junior et al.) which present a comprehensive review of the computation aspects concerning the equivalent-layer technique. The equivalent-layer technique is used widely in processing gravity and magnetic anomalies, e.g., the downward continuation and the reduction to the pole at low latitudes. While such method is very inefficient for dealing with massive data sets, lots of computationally efficient methods have been proposed to reduce its computational cost. The authors from Observatório Nacional and Universidade do Estado do Rio de Janeiro (Brazil) present a comprehensive review of diverse strategies to solve the linear system of the equivalent layer in which the advantages and disadvantages for the existing strategies are described in detail.The second question is about the time-varying gravity (Zhu et al.) which is used in monitoring the subsurface mass variation. Zhu et al., from China Earthquake Administration, have conducted numerous applications focusing on the time-varying gravity in earthquake research in the Chinese Mainland. The gravity changes before

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“…This style of gravity inversions are referred to as geometric inversions. They are typically used to estimate relief of the Moho (e.g Borghi, 2022;Uieda & Barbosa, 2017) or the sediment-basement contact (e.g. Barbosa et al, 2007;Santos et al, 2015).…”

Section: Geometric Inversionsmentioning

confidence: 99%

Airborne Geophysical Investigation beneath Antarctica's Ross Ice Shelf

Tankersley

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The Ross Ice Shelf controls the flow of ice into the ocean from catchments consisting of both the East and West Antarctic Ice Sheets. These catchments hold a volume of ice equivalent to ∼12 m of global sea level rise. To adequately understand how this ice will respond to a warming world requires knowledge of the properties and parameters which influence how the ice sheet behaves. These boundary conditions include fundamental knowledge of the Earth, such as the shape of the bed beneath the ice, the seafloor, and the geologic structures of the upper crust. Knowledge of the physiography and sub-surface geology is severely lacking beneath ice shelves due to their inaccessibility.Here, we use airborne geophysical data from an extensive survey over the Ross Ice Shelf to better understand these boundary conditions. From the analysis of airborne magnetics data, we model the thickness of sediment, the shape of the crystalline basement, and the likely locations of faults throughout the crust under the Ross Ice Shelf. We find a continuous drape of sediment over the seafloor, including deep and narrow fault-bound sedimentary basins beneath the Siple Coast.Using airborne gravity data, and distributed seismic constraints over the ice shelf, we develop and implement a gravity inversion to recover a higher-resolution bathymetry model beneath the ice shelf. This bathymetry model and our quantifica- tion of spatial uncertainty highlight locations likely important for sub-ice shelf ocean circulation and possible recent pinning points. In the process of these geophysical investigations, we reveal a wide range of insights relating to how bathymetry and geology play a critical role in the past, present, and future dynamics of the ice sheet, and how this region has developed over its tectonic history.

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Moho depths for Antarctica Region by the inversion of ground-based gravity data

Cited by 5 publications

References 41 publications

High precision structural mapping using advanced gravity processing methods: a case study from the North region of Cameroon

High precision structural mapping using advanced gravity processing methods: a case study from the North region of Cameroon

Editorial: Applications of gravity anomalies in geophysics

Airborne Geophysical Investigation beneath Antarctica's Ross Ice Shelf

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