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Simulation Explains How the Dwarf Planet Ceres Drives for Surprising Geologic Activity

A clearer picture of Cere's surface, including its composition and architecture, was provided by data and photographs gathered by NASA's Dawn mission

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Russell Chattaraj
Russell Chattaraj
Mechanical engineering graduate, writes about science, technology and sports, teaching physics and mathematics, also played cricket professionally and passionate about bodybuilding.

UNITED STATES: A geoscientist claims that our perception of Ceres has been blurry for a long time. In previous telescopic scans from Earth, Ceres, a dwarf planet and the largest body in the asteroid belt, which is the area between Jupiter and Mars scattered with hundreds of thousands of asteroids, lacked any observable surface features.

The hazy Ceres then became visible in 2015. For scientists, that perspective was breathtaking. A clearer picture of the surface, including its composition and architecture, was provided by data and photographs gathered by NASA’s Dawn mission, which showed geologic activity.

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In prior observations, scientists had glimpsed the general size of Ceres. It was thought to be dormant because it was so small. Instead, Dawn found a sizable plateau on one side of Ceres, about the size of an Earth continent, that covered a portion of the dwarf planet. Rock cracks around it, grouped in one spot.

Additionally, there were obvious signs that this was an ocean world, including deposits everywhere on the surface where minerals had condensed when the water evaporated.

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King’s research on Ceres

King, a professor at the Department of Geosciences who focuses primarily on studying larger bodies like planets, was curious as to how a body as small as Ceres could produce the heat required to support that level of geological activity and account for the surface features observed by Dawn.

He and a group of scientists from various universities, the United States Geological Survey, and the Planetary Science Institute discovered through modelling that Ceres’s interior might remain active due to the decay of radioactive materials. American Geophysical Union Advances recently published their research findings.

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Planets start out hot, as King’s research on large planets like Earth, Venus, and Mars had consistently demonstrated. That initial heat is produced by the collision of the pieces that make up a planet. Ceres, on the other hand, was never large enough to grow into a planet and produce heat in the same way, according to King. 

He studied Ceres’ interior using theories and computational techniques previously applied to larger planets. King searched for evidence that could support his models in data returned by the Dawn mission. He aimed to understand how it could still generate enough heat to power geologic activity.

Ceres began out cold and heated up due to the disintegration of radioactive elements like uranium and thorium, which was enough to power its activity, until the interior became unstable, according to the team’s model of the dwarf planet’s interior.

According to the model, King would see that one area of the interior would suddenly begin to heat up and move higher while the other area would move downward.

Some of the surface characteristics that had formed on Ceres, as revealed by the Dawn mission, may have formed as a result of the instability. The fractures were concentrated around the enormous plateau, which had formed on just one side of Ceres and not on the other. King recognised that there had been instability and that it had left a noticeable influence due to the concentration of features in one hemisphere.

King explained that it was discovered that the model could be used to demonstrate that where one hemisphere had an instability that was rising up, it would result in extension at the surface and be compatible with these patterns of fractures.

According to the team’s hypothesis, Ceres has her unique cool, hot, and cool pattern again, deviating from the conventional pattern of a planet, which is hot first and cool second. According to what we’ve demonstrated in this work, radiogenic heating alone is sufficient to produce intriguing geology, according to King.

He compares the moons of Uranus to Ceres, which a recent study commissioned by NASA and the National Science Foundation said should receive high priority for a significant robotic expedition. He’s also eager to explore their interiors after the model gets some more tweaks.

Some of these moons are roughly Ceres’ size, according to King. Applying the model, in his opinion, would be incredibly exciting.

Also Read: NASA Plans a Bold New Strategy to Find Life on Exoplanets

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  • Russell Chattaraj

    Mechanical engineering graduate, writes about science, technology and sports, teaching physics and mathematics, also played cricket professionally and passionate about bodybuilding.

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