supermassive Archives

This is how a supermassive black hole wakes up

June 6, 2026 by usatoday24

A team of scientists led by Riccardo Middei, from the INAF Astronomical Observatory in Rome, has monitored the step by step of a black hole “resurrecting” after “taking a break.” After monitoring for six years the galaxy that houses ithave been able to see how, after a clear decrease in its brightness, its activity increased significantly. This has allowed them confirm that some standards of physics were very well calculated. However, it has also been detected that some may not have been entirely correct. It’s actually more than six years.. All part of the observations of the Seyfert galaxy ESO 511-G030 that were made in 2007 and 2019 during the mission XMM Newton. It was found that the brightness of the center of the galaxy was 10 times weaker in 2019, whether measured in ultraviolet or when X-rays were detected. A previous detection indicated an increase in 2012, but since there were no measurements between 2012 and 2019, it was not possible to know exactly what happened in that period. The authors of the study that has just been published They wanted to have continuous monitoring, so they took regular data with the Neil Gehrels Swift Observatory from 2019 to 2025. Thus, they saw that, indeed, in 2019 the black hole at the center of the galaxy had practically fallen asleep. However, in 2021 a recovery began to be detected, first in the brightness measured in ultraviolet and then in X-rays. The black hole was waking up. An active galactic nucleus. The Seyfert galaxy is a galactically active nucleus. That is, it emits a brightness higher than that which would correspond to the sum of all its stars. This is because at its center there is an active supermassive black hole. This attracts all matter that gets too close to it. In fact, from a boundary known as the event horizon, not even light can escape. Throughout this process of falling into the black hole, a lot of radiation is emitted. Knowing this, we can see two parts in the black hole. On the one hand, the accretion disk, a rotating ring of hot gas and matter falling into the black hole. During its rotation, it emits optical light and ultraviolet radiation. On the other hand, on this disk is the corona, composed of hot plasma, whose emissions are mainly X-rays. This is the reason why, to measure the activity of a black hole, data are taken in both ultraviolet and Step by step. The reactivation of the black hole occurred in two parts. First of all, the brightness in the ultraviolet clearly increased, between 2021 and 2023. Then, between 2022 and 2023 it was the turn of the X-rays. Therefore, it can be said that first the activity increased in the accretion disk and then in the corona of the black hole. size doesn’t matter. By eliminating the contribution corresponding to the stars of the galaxy, the brightness corresponding to the black hole increased by 20 to 30 times. It was a radical increase in activity, which came at just the right time. And scientists calculate that the transition occurred at just under 1% of its Eddington rate. This is a theoretical figure that describes the universal threshold at which a black hole can accrete or attract matter before radiation pressure expels the incoming gas. For it to truly be a universal figure, as predicted, it would have to be equivalent for both very large black holes and stellar ones. In the stars it has already been measured. Now, in this one, which has a mass equal to 17 million times that of the Sun, the figure is practically the same, so it can be considered universal. What doesn’t add up. The limit from which the black hole “falls asleep and wakes up” seems to coincide with the theory, but there is something that does not fit so much: the speed at which it does so. Both the fade and the recovery occurred too quickly than estimated in the standard models. Therefore, it is clear that the models still have a lot to perfect. To be able to do this, it will be necessary to study more galaxies like this one. Comes into play Vera Rubin Observatoryin which so many astronomers are placing their hopes. Thus, based on observations, the missing piece may be found. Image | POT In Xataka | We already know in which region of the solar system Planet 9 must be (if it really exists)

a supermassive black hole ejected from its galaxy at 3.4 million km/h

December 24, 2025 by usatoday24

Until now, we thought about supermassive black holes like the immovable anchors of galaxies, being gravitational giants that keep everything in order from the center. But we were quite wrong, since the James Webb Space Telescope us has confirmed that, sometimes, these anchors break and are shot through intergalactic space as if they were real gun bullets. The study. A team led by astronomer Pieter van Dokkum of Yale University has presented the first observational confirmation of a wandering supermassive black hole. It is called RBH-1 and its existence is the result of one of the most violent events that physics allows: being “kicked” out of your home by gravitational waves. A scar. Detecting this is not easy, since black holes They cannot be seen with the naked eye, but the destruction they leave in their wake is analyzed. This is precisely what JWST saw when it detected a massive linear structure about 200,000 light years long (twice the diameter of the Milky Way), which connects a distant galaxy with a bright, fuzzy spot. After trying to analyze this destruction in more detail, the telescope itself has revealed that it is a discontinuity. In layman’s terms: there is something extremely massive moving at an absurd speed of 954 km/s, which is equivalent to 3.4 million kilometers per hour. A speed that would allow us to travel from the Earth to the Moon in less than seven minutes. How do we know? The question in this case seems obligatory: How do we know that it is a black hole and not a simple star formation? The answer lies in everything it leaves in its wake, since by moving at this type of high speed, the black hole It compresses the gas so violently that it generates a trail of hot plasma that can be measured, as well as the formation of new stars. And now science has been able to confirm that this gas is not heated by the light emitted by stars, but by the brutal collision of a target that has at least 10 million times the mass of the Sun. Why is he running away? The theory behind this phenomenon is not new, but has been predicted by general relativity for 50 years. But in order to understand what has happened here, we can see it in three different steps: The first thing that happened was the merger of two galaxies and their respective supermassive black holes that began to orbit each other. After this, a third galaxy arrives to join this party and its black hole interacts with the binary system formed before. Finally, a cosmic “kick” is given. In this case, the interaction of three bodies generates a great asymmetry in the gravitational waves that results in a black hole shooting out of the galaxy at a high speed. It’s not the first. We already knew about wandering “stellar mass” black holes (a few times the mass of the Sun) roaming our own Milky Way, detected by gravitational microlensing effects by Hubble or the Gaia mission. However, finding a supermassive, what is the type of object that usually lives in the heart of galaxies, is a milestone on a different scale. Why this matters. The confirmation of RBH-1 is not a simple curiosity for physicists, but validates models of galactic evolution that suggest that the universe is full of these ‘exiles’. And this shows that if supermassive black holes can be ejected so easily, it means that many galaxies could be “orphaned” of their central core, affecting how they grow and form stars. Images | NASA Hubble Space Telescope In Xataka | China is launching more rockets into space than ever before. And the reason is very simple: not to depend on Starlink

a supermassive black hole older than expected

November 28, 2025 by usatoday24

Since the James Webb Space Telescope opened its infrared eyes towards the universe, the truth is that everything beyond our atmosphere has gone from being something calm and a stranger to become in a frantic puzzle For all astrophysicists. Their latest discovery points to the oldest supermassive black hole ever detected, something that gives us more data about the origin of the universe. It has arrived to break the mold. This black hole is located in the galaxy GHZ2and its most relevant fact is not that it is really far away, but when it was formed. Approximations place it just 350 million years after the Big Bang. Something that breaks the classic schemes that experts used, since in theory there would not have been enough time for a gravitational monster of that caliber to grow so much. His discovery. As we say, the protagonist of this story is the galaxy GHZ2/GLASS-z12. A discovery that has been made thanks to the observations of JWST and to the ALMA radio observatory in Chilewhich has confirmed its location through different parameters that place it as the most distant and oldest structure that has ever been confirmed. But what has set off alarm bells is not only its distance, but also its composition, since extremely intense ionized carbon emission lines have been detected. To understand the importance of this finding, you have to know that ionizing carbon at these levels requires a large amount of energy. This means that younger and more massive stars have the capacity to do so, but it is not enough to explain the intensity that has been observed in this galaxy. This means that you have to sign up for a Active Galactic Nucleusthat is to say, a supermassive black hole that is gobbling up matter at a frenetic pace. The time problem. The study suggests that this black hole would have an enormous mass compared to its host galaxy. While in the local universe (ours) the ratio between the mass of the black hole and the stellar mass of the galaxy is around 0.1%, in GHZ2 this ratio could shoot up to 5%. This is something that challenges the training theories that are currently are divided into two sides: Light seeds: black holes are born from the death of the first stars and grow little by little. The problem here is that 350 million years is not enough to reach this size. Heavy seeds: huge clouds of primordial gas have collapsed into black holes to form them, but without becoming a star. The finding of GHZ2 points directly to the second option or to “super-Eddington” feeding episodes (eating faster than radiation pressure theoretically allows). Its importance. If this finding is finally confirmed, we would be facing the absolute record for an active supermassive black hole. Until now, this record was in the UHZ1 galaxy about 470 million years after the Big Bang. But now GHZ2 pushes us more than 100 million years back in time, bringing us dangerously close to the very moment it all began in our universe. What really seems clear is that the universe in its beginning was not a boring or slow place. It was a dynamic, violent and rapid time where galaxies and black holes evolved at a great speed that we are now beginning to understand. Images | BoliviaIntelligent In Xataka | Bad news, the Universe has entered its dying phase. Good news, we won’t be here to see it

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