Abstract
Abstract. This paper examines how the resolution of small-scale geological density models is improved through the fusion of information provided by gravity measurements and density muon radiographies. Muon radiography aims at determining the density of geological bodies by measuring their screening effect on the natural flux of cosmic muons. Muon radiography essentially works like a medical X-ray scan and integrates density information along elongated narrow conical volumes. Gravity measurements are linked to density by a 3-D integration encompassing the whole studied domain. We establish the mathematical expressions of these integration formulas – called acquisition kernels – and derive the resolving kernels that are spatial filters relating the true unknown density structure to the density distribution actually recovered from the available data. The resolving kernel approach allows one to quantitatively describe the improvement of the resolution of the density models achieved by merging gravity data and muon radiographies. The method developed in this paper may be used to optimally design the geometry of the field measurements to be performed in order to obtain a given spatial resolution pattern of the density model to be constructed. The resolving kernels derived in the joined muon–gravimetry case indicate that gravity data are almost useless for constraining the density structure in regions sampled by more than two muon tomography acquisitions. Interestingly, the resolution in deeper regions not sampled by muon tomography is significantly improved by joining the two techniques. The method is illustrated with examples for the La Soufrière volcano of Guadeloupe.
Highlights
Determining the density distribution inside geological structures is of major importance in many domains of Earth sciences
We develop a quantitative methodology to examine how information brought by gravimetry data and by muon radiography may be joined to improve the resolution of density models of highly heterogeneous structures like altered active volcanoes
Thanks to the compact support of muon acquisition kernels, high resolution is achievable in parts of the density model sampled by muon radiography
Summary
Determining the density distribution inside geological structures is of major importance in many domains of Earth sciences. We develop a quantitative methodology to examine how information brought by gravimetry data and by muon radiography may be joined to improve the resolution of density models of highly heterogeneous structures like altered active volcanoes. Resolving kernels only depend on the geometrical properties of the data acquisition (i.e. locations of measurement points and telescope acceptance functions), and they allow one to perform prior analysis to evaluate the model improvements that may be expected by joining additional gravimetric data or muon radiographies. In this way, field measurements may be optimized with respect to the characteristics aimed at for the resulting density model. For the purpose of this article, we simulated 100 measurements regularly spaced on a grid that covers the dome (Fig. 1.1)
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