He James Webb Space Telescope has accustomed us to discoveries that break with our schemes mental The last discovery Where he has been the protagonist, he has undoubtedly re -rethink what we knew about the universe, by confirming the existence of the black hole more distant ever observed. Something that will allow answering some questions that astronomy still had.
A colossus that has already been baptized. This black hole has received the name of Capers-lrd-Z9 And it is 13,300 million light years away, which means that we are seeing it as it was just 500 million years after big Bang. In this way, its existence, and especially the size it has, challenges everything we thought about how these giants grow.
How this black hole was found. Finding something that is so far is not a simple task precisely. Astronomers used program data Capers (Candels-Aea Prism Epoch of Reion Survey) of the James Webb space telescope, specially designed for explore the confines of the universe.
The leader of the research team, Anthony Taylor, Explain that “when looking for black holes, this is the farthest that can be reached in practice. We are really expanding the limits of what current technology can detect.”
A discovery to confirm. The key to confirmation was spectroscopy, the technique that breaks down the light of an objective in its different wavelengths, such as a prism. For Identify an active black holescientists are looking for an unmistakable firm: gas that moves at extreme speeds.
Turning the spiral towards the black hole, the light of the gas that moves away from us will tend towards a red wavelength, and that of the gas approaching is compressed towards the blue length. In this way, if these two trends are found, it is quite unmistakable that a black hole is ‘seeing’.
In this way, the Nirspec Spectrograph The Webb detected a remarkably wide hydrogen emission line, the irrefutable test that a massive object was stirring the gas around it at speeds of up to 3,500 km/s.
It belonged to something bigger. Initially, Capers-LRD-Z9 was just an intriguing motorcycle in webb images. However, it was belonging to a new and enigmatic class of objects called ‘Small red points’ (Little Red Dots or LRDS). These galaxiespresent only in the first 1.5 billion years of the universe, they are extremely compact, bright and as its name indicates very red.
His discovery was “a big surprise,” according to Steven Finkelstein, co -author of the study. “They didn’t look anything like galaxies seen with Hubble.” In this way, this finding has helped explain two of the great mysteries above the table.
Why are they so bright? Its brightness would suggest an unlikely number of stars for such an early era of the universe. In this way, this study confirms the theory that light comes from a supermassive black hole that is active and literally devours the subject. Something that results in hot and shines with a huge intensity.
Why are they so red? The model that best suits the observations of Capers-LRD-Z9 suggests that the black hole is wrapped in a dense and neutral gas environment. This gas cloud absorbs the blue light and lets the red pass, staining the entire galaxy. Something that could be confirmed when comparing this object with other similar sources of energy.
An impossible giant. The most shocking of Capers-LRD-Z9 is the size of its black hole. It is estimated that it could have a mass of up to 300 million times that of our sun. To put it in perspective, it is so massive that it could represent more than 4.5% of the total mass of all the stars of its host galaxy, a proportion much greater than the 0.1% we see in the nearby galaxies.
How could it grow so much and so fast? This is one of the big questions that anyone can ask, taking into account that this black hole appeared at a very early stage of the universe. Something that questions the current models that we have on the table.
Finkelstein summarizes it as follows: “This adds to the growing evidence that primitive black holes grew much faster than we thought were possible. Or they began being much more massive than our models predict.”
Two models to explain its existence. The first of these is that the black hole was not born from a star, but from the direct collapse of a cloud of primary gas, starting its life with a mass of thousands of soles and growing at a normal pace.
The second theory that scientists have on the table is that it was actually born from one of the first massive stars (with a mass 100 times higher than the sun) that existed. The question here is that he would have grown at a rhythm ‘Super-Edington‘, devouring matter much faster than the stable theoretical limit is considered.
There is still much to find out. The team expects to obtain more observations with the Webb to unravel the secrets of this single object. “We had not been able to study the early evolution of black holes until recently,” concludes Taylor, “and we are excited to see what we can learn.”
Images | Nasa Hubble Space Telescope
GIPHY App Key not set. Please check settings