From space to lithosphere: inversion of the GOCE gravity gradients. Supply to the Earth’s interior study

Plasman, Matthieu; Tiberi, Christel; Cadio, C.; Saraswati, Anita Thea; Pajot-Métivier, Gwendoline; Diament, M.

doi:10.1093/gji/ggaa318

Cited by 3 publications

(2 citation statements)

References 55 publications

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“…It provides important information about the geological development, which was previously hidden under an ice sheet several kilometres thick (Ferraccioli et al 2011;Fretwell et al 2013;Hirt 2014;McKenzie et al 2015). The specific value of gravity gradients is shown in Ebbing et al (2018), Sebera et al (2018), Plasman et al (2020).…”

Section: Scientific Resultsmentioning

confidence: 99%

Satellite Gravimetry: A Review of Its Realization

et al. 2021

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Since Kepler, Newton and Huygens in the seventeenth century, geodesy has been concerned with determining the figure, orientation and gravitational field of the Earth. With the beginning of the space age in 1957, a new branch of geodesy was created, satellite geodesy. Only with satellites did geodesy become truly global. Oceans were no longer obstacles and the Earth as a whole could be observed and measured in consistent series of measurements. Of particular interest is the determination of the spatial structures and finally the temporal changes of the Earth's gravitational field. The knowledge of the gravitational field represents the natural bridge to the study of the physics of the Earth's interior, the circulation of our oceans and, more recently, the climate. Today, key findings on climate change are derived from the temporal changes in the gravitational field: on ice mass loss in Greenland and Antarctica, sea level rise and generally on changes in the global water cycle. This has only become possible with dedicated gravity satellite missions opening a method known as satellite gravimetry. In the first forty years of space age, satellite gravimetry was based on the analysis of the orbital motion of satellites. Due to the uneven distribution of observatories over the globe, the initially inaccurate measuring methods and the inadequacies of the evaluation models, the reconstruction of global models of the Earth's gravitational field was a great challenge. The transition from passive satellites for gravity field determination to satellites equipped with special sensor technology, which was initiated in the last decade of the twentieth century, brought decisive progress. In the chronological sequence of the launch of such new satellites, the history, mission objectives and measuring principles of the missions CHAMP, GRACE and GOCE flown since 2000 are outlined and essential scientific results of the individual missions are highlighted. The special features of the GRACE Follow-On Mission, which was launched in 2018, and the plans for a next generation of gravity field missions are also discussed.

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Section: Scientific Resultsmentioning

confidence: 99%

Satellite Gravimetry: A Review of Its Realization

et al. 2021

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“…Plasman inverted the six tensor components of GOCE gravity gradient data and concluded that the simultaneous inversion of several components displayed a significant improvement for the global tensor recovery. The proposed method was successfully verified in complex subduction cases with gradient and gravity data [15]. Residual errors in the terrain correction could lead to errors in data interpretation.…”

Section: Introductionmentioning

confidence: 95%

High-Resolution Cooperate Density-Integrated Inversion Method of Airborne Gravity and Its Gradient Data

Gao

Liu

et al. 2021

Remote Sensing

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Airborne (or satellite) gravity measurement is a commonly used remote sensing method to obtain the underground density distribution. Airborne gravity gradiometry data have a higher horizontal resolution to shallower causative sources than airborne gravity anomaly, so joint exploration of airborne gravity and its gradient data can simultaneously obtain the anomaly feature of sources with different depths. The most commonly used joint inversion method of gravity and its gradient data is the data combined method, which is to combine all the components into a data matrix as mutual constraints to reduce ambiguity and non-uniqueness. In order to obtain higher resolution results, we proposed a cooperate density-integrated inversion method of airborne gravity and its gradient data, which firstly carried out the joint inversion using cross-gradient constraints to obtain two density structures, and then fused two recovered models into a result through Fourier transform; finally, data combined joint inversion of airborne gravity, and gradient data were reperformed to achieve high-resolution density result using fused density results as a reference model. Compared to the data combined joint inversion method, the proposed cooperate density-integrated inversion method can obtain higher resolution and more accurate density distribution of shallow and deep bodies meanwhile. We also applied it to real data in the mining area of western Liaoning Province, China. The results showed that the depth of the skarn-type iron mine in the region is about 900–1300 m and gives a more specific distribution compared to the geological results, which provided reliable data for the next exploration plan.

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