A Single Cosmic Collision May Have Given Us Most Of Our Precious Metals

Without a single, catastrophic collision, precious metals like gold might have been much harder to find than they are. Optimarc/Shutterstock

Precious metals like gold and platinum would be even rarer had it not been for a single collision between Earth and a large body 4.45 billion years ago, a new paper claims. The theory would have major implications for Earth’s early history, the formation of other rocky planets within the Solar System, and even for the composition of Earth-like planets around other stars.

Models of the way planets form have a hard time capturing what we actually see when we look at Mercury, Venus, Earth, the Moon, and Mars.

A team led by Dr Ramon Brasser of the Tokyo Institute of Technology have produced a radically different model, one in which Jupiter collected most of the inner Solar System's rubble, leaving less to rain down on the rocky planets.

The idea stands in contrast to the visions of steady asteroid bombardment over hundreds of millions of years that represent the usual explanation for the minerals near the surface of the planet, and which shape our perceptions of the conditions under which life formed.

Early Earth was so hot that heavy metals with an affinity for iron, among them gold, platinum, and palladium, melted and sunk to the core.

The presence of these elements in the planet's crust can be explained by subsequent asteroid impacts, just as the layer of iridium in 66 million-year-old rocks provided key evidence for the cause of the dinosaurs' extinction.

Brasser agrees precious metals arrived after Earth's crust solidified. However, in Earth and Planetary Science Letters he presents a model that incorporates the controversial Grand Tack theory, under which Jupiter formed closer to the Sun than its current location, and migrated even further in, before shifting outward.

Full Article
Comments

If you liked this story, you'll love these

This website uses cookies

This website uses cookies to improve user experience. By continuing to use our website you consent to all cookies in accordance with our cookie policy.