(Click on the image to view the full diagram.) More than 13 billion years ago, during the era of reionization, the universe was a completely different place. Intergalactic gas is too opaque for energetic light, making young galaxies difficult to observe. What allowed the universe to become completely ionized, or transparent, which eventually led to the “clear” conditions detected in most of the universe today? The James Webb Space Telescope will dig deep into space to gather more information about things that existed during the reionization era to help us understand this profound change in the history of the universe. Credits: NASA, ESA, and J.Kang (STScI)
When Webb looks into the depths of the universe, he is actually looking into the past. The light from this distant quasar began its journey to the Webb when the universe was very young and took billions of years to reach. We will see things as they used to be, not as they are now.
“All the quasars we studied existed very early, when the universe was less than 800 million years old, or less than 6 percent of its present age. So these observations give us an opportunity to study the evolution of galaxies and their formation. and the evolution of these early supermassive black holes. It’s a lot,” explains team member Santiago Arribas, Research Professor in the Department of Astrophysics at the Center for Astrobiology in Madrid, Spain. Arribas is also a member of Webb’s Near Infrared Spectrograph (NIRSpec) Instrument Science Team.
(Click on the image to view the full diagram.) The universe is expanding, and this expansion stretches light across space in a phenomenon known as cosmic redshift. The greater the redshift, the greater the distance traveled by the light. As a result, telescopes equipped with infrared detectors are needed to see light from the first and most distant galaxies. Credits: NASA, ESA, and L. Hustak (STSci)
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The light from this very distant object has been stretched due to the expansion of space. This is known as the cosmic redshift. The further away the light is, the greater the redshift. In fact, visible light from the early universe stretched out in such a way that it turned into infrared radiation when it reached us. With a range of instruments tuned in infrared, Webb is uniquely suited to studying this type of light.
The study of quasars, their galaxies, their host environment, and their powerful currents
The quasars the team will study are not only among the most distant in the universe, but also among the brightest. These quasars usually have the highest black hole mass, and they also have the highest accretion rate – the rate at which material falls into the black hole.
“We were interested in observing the brightest quasars because the extremely high amount of energy they generate in their cores should lead to the greatest impact on the host galaxy through mechanisms such as quasar flow and heating,” said Chris. Willott, a research scientist at the Herzberg Astronomy and Astrophysics Research Center of Canada’s National Research Council (NRC) in Victoria, British Columbia. Willott is also CSA’s Webb Project Scientist. “We wanted to observe these quasars at a time when they had the greatest impact on the host galaxy.”
A large amount of energy is released when matter is accumulated by a supermassive black hole. This energy heats up and pushes the surrounding gas outward, producing a powerful outflow that tore apart interstellar space like a tsunami, causing chaos in the host galaxy.
VIDEO
Watch how the emission and wind from the supermassive black hole affect its parent galaxy – and space hundreds of thousands of light years away for millions of years. Credits: NASA, ESA, and L. Hustak (STScI)
Outflows played an important role in the evolution of galaxies. Gas triggers star formation, so when gas is removed due to outflow, the rate of star formation decreases. In some cases, the outflow is so strong that it emits large amounts of gas that can completely stop star formation within the host galaxy. Scientists also believe that outflow is the primary mechanism by which gas, dust, and elements are redistributed over great distances within galaxies or may even be ejected into intergalactic space – the intergalactic medium. This can trigger fundamental changes in the properties of the parent galaxy and the intergalactic medium.
Examining the properties of intergalactic space during the reionization era
More than 13 billion years ago, when the universe was very young, the scene was far from clear. Neutral gas between galaxies has made the universe opaque for some types of light. Over hundreds of millions of years, neutral gases in the intergalactic medium have become charged or ionized, making them transparent to ultraviolet light. This period is called the reionization era. But what causes the reionization that creates the “clear” conditions detected in much of the universe today? Webb will investigate space to gather more information about this major transformation in the history of the universe. Observations will help us understand the era of reionization, one of the main frontiers in astrophysics.
The team will use the quasar as a backlight source to study the gas between us and the quasar. This gas absorbs quasar light at certain wavelengths. Through a technique called imaging spectroscopy, they will look for absorption lines in the interfering gas. And the brighter the quasar, the stronger the absorption line features in the spectrum. By determining whether a gas is neutral or ionized, scientists will study how neutral the universe is and how much of this reionization process occurs at any given point in time.
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The James Webb Space Telescope will use an innovative instrument called the Integrated Field Unit (IFU) to capture both the image and the spectrum simultaneously. This video provides a basic overview of how IFU works. Credits: NASA, ESA, CSA, and L. Hustak (STScI)
“If you want to study the universe, you need a very bright background source. Quasars are perfect things in the distant universe, because they are quite luminous,” said team member Camilla Pacifici, who is affiliated with the Canadian Space Agency but works as an instrument scientist at the Space Telescope Science Institute. So we can see it very well. In Baltimore. “We want to study the early universe because the universe evolved, and we want to know how it started.”
The team will analyze the light coming from the quasar using NIRSpec to look for what astronomers call “metals,” elements heavier than hydrogen and helium. These elements formed in the first stars and the first galaxies and were ejected by the outflow. The gas moves out of the galaxy in which it was originally located and into the intergalactic medium. The team plans to measure this first generation of “metals,” as well as the way they were pushed into the intergalactic medium by these early outflows.
The power of the web
The Webb is a very sensitive telescope capable of detecting very low levels of light. This is important, because even though a quasar is intrinsically very bright, what the team will observe is one of the most distant objects in the universe. In fact, they were so far apart that the signal Webb would receive was very, very low. Only with Webb’s extraordinary sensitivity can this knowledge be attained. Webb also provides excellent angular resolution, which makes it possible to separate the quasar’s light from its host galaxy.
The quasar program described here is Guaranteed time record involving the spectral capabilities of NIRSpec.
The James Webb Space Telescope will become the world ’s premier space science observatory when it launches in 2021. Webb will solve the mysteries of our solar system, look beyond the distant worlds around other stars, and investigate the mysterious structure and origin of the universe and our place. inside it. Webb is an international program led by NASA with partners ESA (European Space Agency) and Canadian Space Agency.
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