Jupiter was huge when the solar system was still young NASA, ESA, and A. Simon (NASA Goddard)
It鈥檚 one hell of a bowling ball. A comparison of meteorites has revealed that, in its youth, Jupiter carved a path through the solar system that separated space rocks into two separate families. And it did it within a million years of the dawn of the solar system, so Jupiter was already huge at least 4 billion years ago.
Meteorites found on Earth have different proportions of isotopes of the elements in them, depending on whether they are from a rock that originated inside or outside Jupiter鈥檚 orbit. Differences between the rocks are seen even in those chipped off planetesimals that were formed within a million years of the solar system鈥檚 formation, so they must have separated before that.
To have been big enough to carve such a gap in the protoplanetary disk 鈥 a cloud of dense gas and dust orbiting the newly formed sun 鈥 Jupiter鈥檚 core would have to have been about 20 times the mass of Earth. This new meteorite analysis, by Thomas Kruijer at the University of M眉nster in Germany and his colleagues, indicates the Jupiter must have reached that size within the solar system鈥檚 first million years.
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聽Divisive youth
Jupiter is thought to have formed like other gas giants: its rocky core came first, then it gradually accreted more material from the dust and gas around the sun, and later acquired its gassy envelope.
Kruijer鈥檚 team analysed 19 iron meteorites found on Earth that originated from small bodies that formed alongside Jupiter. The isotopes of elements in the rocks that formed inside Jupiter鈥檚 orbit had more elements of the type that are slowly built up in stars, whereas the ones from farther out in the solar system were enriched in the heavy elements that form faster in high-energy situations.
鈥淭hese isotopic labels get carried around by very small dust grains,鈥 says at the University of California, Santa Cruz. 鈥淪omehow, you have to set up a situation in which these little dust grains get mixed around one part of the solar system but not the other.鈥
Some of the isotopes in the meteorites from outside Jupiter鈥檚 orbit are over half a million years younger, which means after Jupiter divided the disc, they were unable to hop the gap into the inner area.
鈥淲e need more evidence that says this is where those two meteorite classes form – one inward and one outward,鈥 says at Cornell University in New York. 鈥淏ut it鈥檚 a very nice measurement.鈥
Tacked on
The work supports one of the leading theories of the early solar system 鈥 the grand tack hypothesis. This supposes that Jupiter was born a few million years before Saturn and its enormous mass was tugged towards the sun. Once Saturn formed, however, its gravity pulled Jupiter back from the brink of stellar destruction and towards the outer solar system.
These two drifts across the solar system meant Jupiter crashed through the asteroid belt twice, mixing the two types of objects in the asteroid belt, leaving behind the well-mixed objects we see today.
鈥淭he really striking thing is that the grand tack was proposed before anyone knew about this isotopic labeling, but the isotopes really seem to agree well with the grand tack,鈥 says Nimmo. 鈥淭hat鈥檚 kind of powerful.鈥
鈥淚t鈥檚 a really neat story,鈥 says Nimmo, 鈥渁nd I think it鈥檚 probably right.鈥
Proceedings of the National Academy of Sciences
Read more: Mars is so small because Jupiter shook up its formation
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