View of the half-illuminated Moon surrounded by black space
Researchers are developing a new technique to help visualize the complex internal layering and anomalous structures inside planetary bodies, including the Moon. Credit: NGC 54/Wikimedia, CC BY-SA 4.0
Source: Earth and Space Science

Getting to know planets or moons inside out isn’t easy. Like Earth and its Moon, many celestial bodies are multilayered and can contain anomalous internal features that reflect the complex history of their formation, collisions with other bodies, and ongoing planetary dynamics.

Anomalous structures inside planets and moons that have different densities compared with their surroundings can be detected using gravity data. Above such density anomalies, the force of gravity acting on spacecraft traveling nearby is higher or lower than at other locations.

Computational techniques known as gravity inversions relate differences in gravity acceleration to differences in internal density structure. Now, Izquierdo et al. present a novel technique that may help researchers infer the global structure of a planet or moon from the gravity acceleration data measured by orbiting spacecraft.

Compared with traditional methods, the new technique, dubbed THeBOOGIe (short for transdimensional hierarchical Bayesian object-oriented gravity inversion), allows more flexibility in inputting known geological and geographical data, and it does not require researchers to input a depth range of interest or information on a known internal density interface.

THeBOOGIe applies a Bayesian statistical approach that starts with a randomly generated model of a planet’s or moon’s interior. The model is then refined through hundreds of thousands of iterations until it best fits the input gravitational, geological, and geographical data.

The researchers tested the approach by applying it to determine the Moon’s interior structure using synthetic input gravitational data that were representative of real lunar data. They found that the technique correctly identified the location and width of density anomalies in the lunar crust and mantle. However, it overestimated the vertical thickness of crustal anomalies.

The researchers note that THeBOOGIe, which could be refined through additional work, is well suited for complementing models of planetary interiors based on seismic data and for determining the internal features of smaller bodies without a perfectly layered structure. They also point out that the flexibility and statistical strength of THeBOOGIe may help scientists visualize the interiors of planets and moons for which seismic and geophysical data are lacking. (Earth and Space Science,, 2023)

—Sarah Stanley, Science Writer

Citation: Stanley, S. (2023), Visualizing the deep insides of planets and moons, Eos, 104, Published on 10 August 2023.
Text © 2023. AGU. CC BY-NC-ND 3.0
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