Latest news with #NuSTAR
Yahoo
21-06-2025
- Science
- Yahoo
Turns out supermassive black holes are way more common than we thought
If you purchase an independently reviewed product or service through a link on our website, BGR may receive an affiliate commission. Supermassive black holes are some of the densest objects found within our universe. These cosmic objects are so heavy that they often weigh billions of times more than our sun, and they're so dense, not even light can escape their grasp. For the most part, we've believed these massive beasts were only found at the center of galaxies. However, new research suggests they might be far more common than we thought. The new study, which is published in The Astrophysical Journal, used data from NASA's InfraRed Astronomy Satellite and the NuSTAR X-ray telescope, which is operated by NASA/JPL. By looking at data from both the infrared and x-ray spectrums, they were able to determine that several of these cosmic objects managed to slip past earlier observations. Today's Top Deals Best deals: Tech, laptops, TVs, and more sales Best Ring Video Doorbell deals Memorial Day security camera deals: Reolink's unbeatable sale has prices from $29.98 Supermassive black holes should be pretty hard to miss. Just like Sagittarius A*, the black hole at the center of the Milky Way is. While you can't expect see them by going outside and looking up from your backyard, their enormous mass causes ripples and distortions in space, which isn't hard to spot when viewing the universe through a powerful telescope. Despite the immense pull these objects have on the universe, it's still possible to miss them due to unexpected readings or even things like gravitational lensing from other galaxies. And since we still don't know how black holes evolve, there's only so much we can do to spot them. Not to mention there are a ton of less active, silent black holes out there that aren't siphoning off matter and light anymore. So, how exactly did the researchers spot new black holes? Well, according to the findings, they looked at how gas and dust emit light after being heated. From there, they were able to spot several new supermassive black holes hidden in the cosmos. We know that sometimes these cosmic objects can break free of their galaxies, leading to rogue black holes, so it's not too surprising that there are more of them than we previously expected. This is all part of a growing attempt to understand more about how dust interacts within the universe as a whole, and what's going on behind it. While there are likely still thousands (if not millions) of black holes we have yet to discover, this new research at least tells us it is worth looking harder. More Top Deals Amazon gift card deals, offers & coupons 2025: Get $2,000+ free See the
Time of India
28-04-2025
- Science
- Time of India
Int'l physics conference concludes at PU
Chandigarh: An international conference organised by the physics department of Panjab University concluded successfully recently. Titled 'Theme Meeting on FAIR (Facility for Antiproton and Ion Research) Science', the event provided a platform for scientists, researchers, and students to engage in discussions about advancements in physics and interdisciplinary research. The inaugural session was attended by prominent guests, including Kaustav Sanyal (director, Bose Institute, Kolkata), Meenakshi Goyal (director, R&D Centre, Panjab University), and Nagaboopathy Mohan (international cooperation division, department of science and technology, GoI). The conference saw the participation of nine foreign scientists and delegates from FAIR-GSI (Gesellschaft für Schwerionenforschung), Germany, alongside nearly 50 prominent scientists from Indian institutions such as IITs, NISER, IISERs, VECC, BARC, and TIFR. Outreach activities engaged approximately 100 students from institutions within the Chandigarh region, fostering interest in research in advanced scientific fields. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Co-Founder of Google Brain, Andrew Ng, Is Reported To Have Read Every... Blinkist: Andrew Ng's Reading List Undo The discussions focused on topics like heavy-ion physics , nuclear structure, astrophysics , and their medical and biophysics applications. The event encouraged collaborative exchanges between Indian and German scientists, especially regarding future partnerships in the CBM and NuSTAR programs. The meeting was organised by Bivash R Behera and Lokesh Kumar from PU's department of physics.
Yahoo
11-02-2025
- Science
- Yahoo
A Strange New Cosmic Explosion May Have Just Been Discovered
A bizarre cosmic explosion has puzzled astronomers. It's either a very rare case of the stars aligning just right (literally) – or something powerful never seen before. The event is designated EP240408a, as it was first detected by the Einstein Probe, an X-ray space telescope, on 8 April 2024. At a glance, it appeared to be a run-of-the-mill gamma ray burst, which typically emits bright X-rays too. But when an all-star cast of telescopes observed it in a range of wavelengths, including ultraviolet, optical, near-infrared, radio, X-rays, and gamma rays, they found that it didn't quite match any particular known type of event. The current leading explanation, according to a new study, is that it's the death throes of a white dwarf being torn apart by a medium-sized black hole. This created a high-speed jet of material that, as luck would have it, is pointing directly at Earth. "EP240408a ticks some of the boxes for several different kinds of phenomena, but it doesn't tick all the boxes for anything," says Brendan O'Connor, astronomer at Carnegie Mellon University and lead author of the study. "In particular, the short duration and high luminosity are hard to explain in other scenarios. The alternative is that we are seeing something entirely new!" The Universe is ablaze with transient events – energetic flashes caused by outbursts from stars and black holes, stars exploding as supernovae, stars being devoured by black holes, and all kinds of other cosmic drama. Astronomers can figure out what each event is by its duration, frequency, source, and the specific combination of wavelengths it emits. After its discovery by the Einstein Probe, EP240408a was observed by a squad of other ground- and space-based telescopes, including the Nuclear Spectroscopic Telescope Array (NuSTAR), Swift, Gemini, Keck, the Dark Energy Camera (DECam), the Very Large Array (VLA), the Australia Telescope Compact Array (ATCA), and the Neutron star Interior Composition Explorer (NICER). Armed with this data, astronomers pieced together the event's properties – but that only deepened the mystery. EP240408a flared up in soft X-rays for the first 10 seconds, plateaued at a steady glow for about four days, then faded quickly within another day. That's much longer than most gamma-ray bursts, which last up to several hours, but not long enough to fit into other known categories. Its brightness in X-rays was in a similar reverse-Goldilocks zone: too bright for some phenomena and not bright enough for others. Weirdest of all, the VLA saw no sign of radio emission from the source when it checked 11 days, 158 days, and 258 days after the initial flare-up. "When we see something this bright for this long in X-rays, it usually has an extremely luminous radio counterpart," says O'Connor. "And here we see nothing, which is very peculiar." After ruling out several possible explanations, such as quasars or the mysterious fast blue optical transients, the astronomers put forward the most likely culprit: a tidal disruption event (TDE). These are flashes of light thrown off when black holes messily gobble up stars. In rare cases, TDEs produce huge jets of material that blast off from the black hole's poles. These can, by chance, point straight towards Earth, which produces the signature seen. The characteristics of the signal suggest that specifically, it was an intermediate-mass black hole chowing down on a white dwarf star. The thing is, there should still be some radio emissions from a jetted TDE. The team's hypothesis for why none have been found so far is that the event was caught too early – previous research suggests that it can take hundreds or even thousands of days for jet material to slow down enough to begin beaming radio signals. If future observations do detect radio emissions, this could close the case on EP240408a. But if it stays silent, it could mean it's a particularly weird gamma-ray burst – or perhaps a brand new type of transient. The research was published in The Astrophysical Journal Letters. Astronomers Amazed by Perfect 'Einstein Ring' Gleaming in Space Astronomers Capture Breathtaking Image of Newborn Star Taking Shape The Risk of Space Junk Hitting Planes Is Rising in The Era of SpaceX
