The universe 13,000 million years ago was very different from the universe we know today.
It is understood that stars were forming at a very rapid rate, as the first dwarf galaxies came into being and later merged to give rise to the more massive present-day galaxies, including our own. However, the exact chain of the events which produced the Milky Way was not known until now.
Exact measurements of position, brightness and distance for around a million stars of our galaxy within 6,500 light years of the sun, obtained with the Gaia space telescope, have allowed a team from the IAC to reveal some of its early stages.
“We have analyzed, and compared with theoretical models, the distribution of colours and magnitudes (brightness) of the stars in the Milky Way, splitting them into several components; the so-called stellar halo (a spherical structure which surrounds spiral galaxies) and the thick disc (stars forming the disc of our Galaxy, but occupying a certain height range),” explained Carme Gallart, a researcher at the IAC and the first author of this article, which is published this week in the journal Nature Astronomy.
Previous studies had discovered that the Galactic halo showed clear signs of being made up of two distinct stellar components, one dominated by bluer stars than the other. The movement of the stars in the blue component quickly allowed us to identify it as the remains of a dwarf galaxy (Gaia-Enceladus) which impacted onto the early Milky Way. However, the nature of the red population, and the epoch of the merger between Gaia-Enceladus and our Galaxy were unknown.
“Analyzing the data from Gaia has allowed us to obtain the distribution of the ages of the stars in both components and has shown that the two are formed by equally old stars, which are older than those of the thick disc,” said IAC researcher and co-author Chris Brook. But if both components were formed at the same time, what differentiates one from the other?
“The final piece of the puzzle was given by the quantity of “metals” (elements which are not hydrogen or helium) in the stars of one component or the other,” explained Tomás Ruiz Lara, an IAC researcher. “The stars in the blue component have a smaller quantity of metals than those of the red component.”
These findings, with the addition of the predictions of simulations which are also analyzed in the article, have allowed the researchers to complete the history of the formation of the Milky Way.
Thus, 13,000 million years ago stars began to form in two different stellar systems which then merged: one was a dwarf galaxy which we call Gaia-Enceladus, and the other was the main progenitor of our Galaxy, some four times more massive and with a larger proportion of metals. Some 10,000 million years ago there was a violent collision between the more massive system and Gaia-Enceladus. As a result, some of its stars, and those of Gaia-Enceladus were set into chaotic motion, and eventually formed the halo of the present Milky Way. After that there were violent bursts of star formation until 6,000 million years ago, when the gas settled into the disc of the Galaxy, and produced what we know as the “thin disc.”
Until now all the cosmological predictions and observations of distant spiral galaxies similar to the Milky Way indicate that this violent phase of merging of smaller structures was very frequent. Now researchers have been able to identify the specificity of the process in our own Galaxy, revealing the first stages of our cosmic history with unprecedented detail.
The universe 13,000 million years ago was very different from the universe we know today. It is understood that stars were forming at a very rapid rate, forming the first dwarf galaxies, whose mergers gave rise to the more massive present-day galaxies, including our own. Credit: Gabriel Pérez Díaz, SMM (IAC)