Collisions Not Needed For Star Formation
ESA’s Herschel infrared space observatory has discovered that galaxies do not need to collide with each other to drive vigorous star birth. The finding overturns this long-held assumption and paints a more stately picture of how galaxies evolve.
The conclusion is based on Herschel’s observations of two patches of sky, each about a third of the size of the full Moon.
It’s like looking through a keyhole across the Universe — Herschel has seen more than a thousand galaxies at a variety of distances from the Earth, spanning 80% of the age of the cosmos.
These observations are unique because Herschel can study a wide range of infrared light and reveal a more complete picture of star birth than ever seen before.
It has been known for some years that the rate of star formation peaked in the early Universe, about 10 billion years ago. Back then, some galaxies were forming stars ten or even a hundred times more vigorously than is happening in our Galaxy today.
In the nearby, present-day Universe, such high birth rates are very rare and always seem to be triggered by galaxies colliding with each other. So, astronomers had assumed that this was true throughout history.
Herschel now shows that this is not the case by looking at galaxies that are very far away and thus seen as they were billions of years ago.
David Elbaz, CEA Saclay, France, and collaborators have analyzed the Herschel data and find that galaxy collisions played only a minor role in triggering star births in the past, even though some young galaxies were creating stars at furious rates.
By comparing the amount of infrared light released at different wavelengths by these galaxies, the team has shown that the star birth rate depends on the quantity of gas they contain, not whether they are colliding.
Gas is the raw building material for stars and this work reveals a simple link: the more gas a galaxy contains, the more stars are born.
“It’s only in those galaxies that do not already have a lot of gas that collisions are needed to provide the gas and trigger high rates of star formation”, says Dr Elbaz.
This applies to today’s galaxies because, after forming stars for more than 10 billion years, they have used up most of their gaseous raw material.
The research paints a much more stately picture of star births than before, with most galaxies sitting in space, growing slowly and naturally from the gas they attract from their surroundings.
“Herschel was conceived to study the history of star formation across cosmic time”, says GÃ¶ran Pilbratt, ESA Herschel Project Scientist.
“These new observations now change our perception of the history of the Universe.”
Image 1: A galaxy accretes mass from rapid, narrow streams of cold gas. These filaments provide the galaxy with continuous flows of raw material to feed its star-forming at a rather leisurely pace. This theoretical scenario for galaxy formation is based on the numerical simulations presented by Dekel et al., 2009 (Nature, 457, 451D). However, the actual process of stream accretion onto a galaxy has never been directly observed and it remains speculative. Credits: ESA—AOES Medialab
Image 2: GOODS-North is a patch of sky in the northern hemisphere that covers an area of about a third the size of the Full Moon. This images was taken by Herschel at the following infrared wavelengths: 100Î¼m (blue), 160Î¼m (green) and 250Î¼m (red). North is up and East is left. Credits: ESA/GOODS-Herschel consortium/David Elbaz
Image 3: GOODS-South is a patch of sky in the southern hemisphere that covers an area of about a third the size of the Full Moon. This images was taken by Herschel and NASA’s Spitzer space telescope at the following infrared wavelengths:24 Î¼m (blue), 100 Î¼m (green) and 160 Î¼m (red). North is up and East is left. Credits: ESA/GOODS-Herschel consortium/NASA/JPL-Caltech/David Elbaz
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