The early solar system was more chaotic than previously thought, according to a new, more precise reconstruction of the early history of several asteroids.
Before the Earth and other planets formed, the young sun was still surrounded by cosmic gas and dust.
Over the millennia, rock fragments of various sizes formed from the dust. Many of these became building blocks for the later planets.
Others did not become part of a planet and still orbit the sun today, for example as asteroids in the asteroid belt.
Researchers analyzed iron samples from the cores of such asteroids that landed on Earth as meteorites. In doing so, they unraveled part of their early history during the time when planets formed.
Solar system chaos
“Previous scientific studies showed that asteroids in the solar system have remained relatively unchanged since their formation, billions of years ago,” says Alison Hunt, a researcher at ETH Zurich and the National Centre of Competence in Research PlanetS (NCCR PlanetS) and lead author of the paper in Nature Astronomy.
“They therefore are an archive, in which the conditions of the early solar system are preserved.”
But to unlock this archive, the researchers had to thoroughly prepare and examine the extra-terrestrial material.
The team took samples from 18 different iron meteorites, which were once part of the metallic cores of asteroids.
To carry out their analysis, they had to dissolve the samples to be able to isolate the elements palladium, silver, and platinum for their detailed analysis.
With the help of a mass spectrometer, they measured abundances of different isotopes of these elements.
Isotopes are distinct atoms of given elements, in this case palladium, silver, and platinum, which all share the same number of protons in their nuclei but vary in the number of neutrons.
In the first few million years of our solar system, radioactive decay of isotopes heated the metallic asteroid cores.
As they began to cool down, a specific silver isotope produced by radioactive decay began to accumulate. By measuring the present-day silver isotope ratios within the iron meteorites, the researchers could determine both when and how quickly the asteroid cores had cooled.
The results showed that the cooling was rapid and likely occurred due to severe collisions into other bodies, which broke off the insulating rocky mantle of the asteroids and exposed their metal cores to the cold of space.
While the fast cooling had been indicated by previous studies based on silver isotope measurements, the timing had remained unclear.
“Our additional measurements of platinum isotope abundances allowed us to correct the silver isotope measurements for distortions caused by cosmic irradiation of the samples in space. So we were able to date the timing of the collisions more precisely than ever before,” Hunt says.
“And to our surprise, all the asteroidal cores we examined had been exposed almost simultaneously, within a timeframe of 7.8 to 11.7 million years after the formation of the solar system.”
The near simultaneous collisions of the different asteroids indicated that this period must have been a very unsettled phase of the solar system. “Everything seems to have been smashing together at that time,” Hunt says. “And we wanted to know why.”
Planet births
The team considered different causes by combining their results with those from the latest, most sophisticated computer simulations of the solar system development. Together, these sources could narrow down the possible explanations.
“The theory that best explained this energetic early phase of the solar system indicated that it was caused primarily by the dissipation of the so-called solar nebula,” says coauthor Maria Schönbächler, professor of cosmochemistry at ETH Zurich and NCCR PlanetS member.
“This solar nebula is the remainder of gas that was left over from the cosmic cloud out of which the sun was born. For a few million years, it still orbited the young sun until it was blown away by solar winds and radiation.”
While the nebula was still around, it slowed down the objects orbiting the sun in it—similar to how air resistance slows a moving car. After the nebula had disappeared, so the researchers suggest, the lack of gas drag allowed the asteroids to accelerate and collide into each other—like bumper cars that were turned to turbo-mode.
“Our work illustrates how improvements in laboratory measurement techniques allow us to infer key processes that took place in the early solar system—like the likely time by which the solar nebula had gone,” Schönbächler says.
“Planets like the Earth were still in the process of being born at that time. Ultimately, this can help us to better understand how our own planets were born, but also give us insights into others outside our solar system.”