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Scientists discover new evidence of intermediate-mass black holes

A series of studies sheds light on the origins and characteristics of intermediate-mass black holes. In the world of black holes, there are generally three size categories: stellar-mass black holes (about five to 50 times the mass of the sun), supermassive black holes (millions to billions of times the mass of the sun), and intermediate-mass black holes with masses somewhere in between.

While we know that intermediate-mass black holes should exist, little is known about their origins or characteristics – they are considered the rare “missing links” in black hole evolution.

However, four new studies have shed new light on the mystery. The research was led by a team in the lab of Assistant Professor of Physics and Astronomy Karan Jani, who also serves as the founding director of the Vanderbilt Lunar Labs Initiative. The work was funded by the National Science Foundation and the Vanderbilt Office of the Vice Provost for Research and Innovation.

Telescopes in Chile Capture Images of the Earliest Galaxies in the Universe

Thanks to observatories like the venerable Hubble Space Telescope (HST) and its next-generation cousin, the James Webb Space Telescope (JWST), astronomers are finally getting the chance to study galaxies that existed just one billion years after the Big Bang. This period is known as “Cosmic Dawn” because it was during this period that the first stars formed and came together to create the first galaxies in the Universe. The study of these galaxies has revealed some surprising and fascinating things that are allowing astronomers to learn how large-scale structures in the Universe came to be and how they’ve evolved since.

For the longest time, it was thought that this cosmological period could only be seen by space telescopes, as they don’t have to deal with interference from Earth’s atmosphere. With advanced technologies ranging from adaptive optics (AO) and coronagraphs to interferometry and spectrometers, ground-based telescopes are pushing the boundaries of what astronomers can see. In recent news, an international team of astronomers using the Cosmology Large Angular Scale Surveyor (CLASS) announced the first-ever detection of radiation from the cosmic microwave background (CMB) interacting with the first stars in the Universe. These findings shed light on one of the least understood periods in cosmological history.

The study that details their findings, which recently appeared in The Astrophysical Journal, was led by Yunyang Li — an observational cosmologist from the Kavli Institute for Cosmological Physics (University of Chicago) and The William H. Miller III Department of Physics and Astronomy at Johns Hopkins University (JHU). He was joined by many JHU colleagues, as well as astrophysicists from the National Institute of Standards and Technology, the Argonne National Laboratory, the Los Alamos National Laboratory, the Harvard-Smithsonian Center for Astrophysics, the Massachusetts Institute of Technology (MIT), the NASA Goddard Space Flight Center, and many prestigious universities.

‘Black hole bomb’ discovery could trigger potential ‘catastrophic’ disaster if it ever detonated

The AI bot explained: If a black hole bomb were somehow constructed and detonated, the energy release could be comparable to that of a supernova, one of the most powerful explosions in the universe. Such an event would release vast amounts of radiation and could have devastating effects on its surroundings.

30 Space Phenomena That Are Still a Mystery

Dark matter constitutes about 27% of the universe, yet it remains one of the greatest mysteries in cosmology. Unlike normal matter, it does not emit, absorb, or reflect light, making it invisible and detectable only through its gravitational effects. Understanding dark matter is crucial for explaining galaxy formation and cosmic structure.

Accounting for approximately 68% of the universe, dark energy is a hypothetical form of energy proposed to explain the accelerated expansion of the universe. Its nature and properties remain unclear. Dark energy challenges our understanding of gravity and the ultimate fate of the cosmos.

Black holes are regions with a gravitational pull so strong that nothing, not even light, can escape. While we have theories describing their behavior, their interiors remain shrouded in mystery. The existence of black holes challenges the boundaries of our understanding of physics, including general relativity and quantum mechanics.

Universe was not formed in big bang but ‘bounced’ out of black hole — new study

We’ve questioned that model and tackled questions from a different angle – by looking inward instead of outward.

Instead of starting with an expanding universe and asking how it began, we considered what happens when an over-density of matter collapses under gravity.

Prof Gaztanaga explained that the theory developed by his team of researchers worked within the principles of quantum mechanics and the model could be tested scientifically.

Deciphering the behavior of heavy particles in the hottest matter in the universe

An international team of scientists has published a new report that moves toward a better understanding of the behavior of some of the heaviest particles in the universe under extreme conditions, which are similar to those just after the Big Bang.

The review article, published in the journal Physics Reports, is authored by physicists Juan M. Torres-Rincón, from the Institute of Cosmos Sciences at the University of Barcelona (ICCUB), Santosh K. Das, from the Indian Institute of Technology Goa (India), and Ralf Rapp, from Texas A&M University (United States).

The authors have published a comprehensive review that explores how particles containing (known as charm and bottom hadrons) interact in a hot, dense environment called hadronic matter. This environment is created in the last phase of high-energy collisions of atomic nuclei, such as those taking place at the Large Hadron Collider (LHC) and the Relativistic Heavy Ion Collider (RHIC).

Earth-based telescopes offer a fresh look at Cosmic Dawn

For the first time, scientists have used Earth-based telescopes to look back over 13 billion years to see how the first stars in the universe affect light emitted from the Big Bang.

Using telescopes high in the Andes mountains of northern Chile, astrophysicists have measured this polarized microwave light to create a clearer picture of one of the least understood epochs in the history of the universe, the Cosmic Dawn.

“People thought this couldn’t be done from the ground. Astronomy is a technology-limited field, and from the Cosmic Dawn are famously difficult to measure,” said Tobias Marriage, project leader and a Johns Hopkins professor of physics and astronomy. “Ground-based observations face additional challenges compared to space. Overcoming those obstacles makes this measurement a significant achievement.”

Cosmic Rule-of-Thumb

If we chose to shovel matter along a straight line through the observable Universe, what is the average mass of matter per unit area that our shovel will collect? To answer this question, I did a simple calculation before my morning jog at sunrise today.

The answer depends on how far the shovel goes. Projecting all the matter out to the farthest galaxy, MoM-z14, discovered last month by the Webb telescope at a cosmic redshift 14.44 or equivalently 280 million years after the Big Bang, the answer is about 0.5 grams per square centimeter, of order the mass per unit area of a thumb. This establishes the cosmic rule-of-thumb: the observable universe yields on average as much mass per unit area as a thumb.

This mass budget includes mostly dark matter whose nature is unknown. Ordinary matter accounts for only 16% of the total budget or 0.08 grams per square centimeter out to MoM-z14, of order the surface mass density of a fingernail.

The Maker of Universes by Philip José Farmer, World of Tiers #1, a Journey Through Multiverse & Myth

🔮 Step into a world of infinite possibilities with “The Maker of Universes” by Philip José Farmer—a groundbreaking science fiction novel that explores the boundaries of reality, mythology, and the human psyche across multiple universes. 🚀🌌 In this visionary tale, we follow the story of Robert Wolff, an Earthling who finds himself transported to the mysterious world of Tiers, a place where gods and mortals coexist, and where the boundaries between myth and reality blur. As Robert navigates this surreal landscape, encountering enigmatic beings, ancient prophecies, and cosmic mysteries, he discovers his role as a pivotal figure in the fabric of Tiers’ existence. Join us as we delve into the rich tapestry of “The Maker of Universes.” From the awe-inspiring landscapes and mythological creatures to the philosophical questions about the nature of creation and existence, Farmer’s novel offers a mind-bending exploration of alternate realities and the power of imagination. Our video immerses you in the fantastical realms of “The Maker of Universes,” delving into the themes of identity, destiny, and the interplay between myth and reality. We explore the intricate world-building, the diverse cultures, and the profound insights into human nature that make this novel a timeless gem in the science fiction and fantasy genre. Whether you’re a fan of epic adventures, mythic storytelling, or tales that challenge your perceptions of reality, “The Maker of Universes” promises an enthralling and thought-provoking reading experience that will transport you to realms beyond imagination. Prepare to unlock the secrets of the multiverse and embark on a journey of cosmic discovery with Philip José Farmer’s visionary masterpiece! 🌌📘 #PhilipJoséFarmer #TheMakerOfUniverses #ScienceFantasy #MultiverseAdventure #MythologicalExploration

Self-learning neural network cracks iconic black holes

A team of astronomers led by Michael Janssen (Radboud University, The Netherlands) has trained a neural network with millions of synthetic black hole data sets. Based on the network and data from the Event Horizon Telescope, they now predict, among other things, that the black hole at the center of our Milky Way is spinning at near top speed.

The astronomers have published their results and methodology in three papers in the journal Astronomy & Astrophysics.

In 2019, the Event Horizon Telescope Collaboration released the first image of a supermassive black hole at the center of the galaxy M87. In 2022, they presented an image of the black hole in our Milky Way, Sagittarius A*. However, the data behind the images still contained a wealth of hard-to-crack information. An international team of researchers trained a neural network to extract as much information as possible from the data.