Tag Archives: XMMNewton

XMM-Newton Delivers Incredible X-Ray Images of Interstellar Comet 3I/ATLAS

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Astronomers utilizing ESA’s XMM-Newton Observatory have captured X-ray images of 3I/ATLAS, the third confirmed interstellar object to traverse our solar system, following 1I/Oumuamua and 2I/Borisov.

This XMM-Newton image displays an X-ray visualization of the interstellar comet 3I/ATLAS. The center features a bright red dot against a dark backdrop, resembling a burning lighthouse. Surrounding this core is a soft gradient of purple and blue, forming a slightly rotated rectangular frame divided by a thin horizontal line, indicating the detector gap. Red represents low-energy X-rays, while blue signifies regions with minimal X-rays. Image credit: ESA / XMM-Newton / C. Lisse / S. Cabot / XMM ISO Team.

On December 3, 2025, XMM-Newton tracked the interstellar comet 3I/ATLAS for approximately 20 hours.

During this observation, the interstellar object was about 282-285 million kilometers away from the spacecraft.

XMM-Newton utilized the European Photon Imaging Camera (EPIC)-PN, its most sensitive X-ray camera, to observe the comet.

“This XMM-Newton image highlights the comet radiating in low-energy X-rays. The blue regions indicate voids with nearly no X-rays, while the red areas showcase the comet’s X-ray emissions,” stated members of the XMM-Newton team.

Astronomers anticipated this glow, as gas molecules emitted from comets generate X-rays upon colliding with the solar wind.

“These X-rays can originate from the interaction of the solar wind with gases such as water vapor, carbon dioxide, and carbon monoxide, and have previously been detected by telescopes like NASA/ESA/CSA’s James Webb Space Telescope and NASA’s SPHEREx,” added the researchers.

“However, these telescopes possess distinct sensitivities to gases like hydrogen and nitrogen.”

“They are almost undetectable by optical and ultraviolet instruments, such as the NASA/ESA Hubble Space Telescope and ESA’s JUICE camera.”

“This makes X-ray observation an exceptional resource,” they emphasized.

“Researchers will be able to identify and examine gases that are difficult to detect with alternative instruments.”

“Multiple scientific groups suggest that the first observed interstellar object, 1I/’Oumuamua, may have been composed of unusual ices like nitrogen and hydrogen.”

“Although 1I/Oumuamua is currently too distant to study, 3I/ATLAS provides fresh opportunities to investigate interstellar bodies. X-ray observations will supplement other data and assist scientists in understanding the composition of these objects.”

Source: www.sci.news

XMM-Newton discovers two supernova remnants near the Milky Way satellite galaxy’s edge

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Named SNR J0614-7251 and SNR J0624-6948, the newly discovered supernova remains are located on the outskirts of the large Magelanic Cloud, the largest milky white satellite galaxy.

In the center of the image, stars cluster into a large Magellan cloud, a bright, dark green candy floss colored haze. Scattered in the center of the image are about 50 small yellow crosses, some of which are almost overlapping as they are very close to each other. SNR J0624-6948 (orange, high image) and SNR J0614-7251 (blue, bottom image) are seen in the lower left quarter of the image. Image credits: Eckhard Slawik/ESA/Xmm-Newton/Sasaki et al. / F. Zangrandi.

“Supranovae are stellar explosions, caused by massive star core collapse, neutron stars or black holes (core collapsing supernovae), or by thermonuclear destruction of white nuclei in binary systems. Friedrich- “We are a scientist at the same time,” said Alexander-Universität Erlangen-Nürnberg and colleague Dr. Manami Sasaki.

“Supranovae are important for galaxy material cycles and the formation of next-generation stars. Shockwave produces supernova debris that heats environmental or interstellar media to ionize, sweeping and compressing the environment, and making the environment more environmentally friendly and compressing. Enrich it. With chemical elements.”

use ESA's XMM-Newton Spaceshipastronomers discovered two supernova remnants, SNR J0614-7251 and SNR J0624-6948, in the large Magellan cloud.

“The big and small Magellan clouds are the largest satellite galaxies in the Milky Way and the closest ones,” they said.

“The Magellan Cloud is also the only satellite galaxy in the Milky Way with current active star formation.”

“A large Magellan cloud at a small distance (49,600 Parsec), its morphology is almost a hassle disk, and its low foreground absorption provides a detailed laboratory ideal for the study of large samples of the remaining supernovae. Masu.”

“Proximity allows for spatially resolved spectroscopic studies of supernova debris, and precisely known distances allow for the analysis of the energetics of each supernova debris.”

“In addition, the rich data of wide-field multi-wavelength data available provides information about the environment in which these supernova debris evolves.”

XMM-Newton observed SNR J0614-7251 and SNR J0624-6948 with three different types of X-ray light.

They show the most common chemical elements in various parts of the debris.

The center of SNR J0614-7251 is primarily made up of iron, according to the team.

This clue allowed researchers to classify this remnant for the first time as a result of a type IA supernova.

“The discovery of supernova remnants on the outskirts of the large Magellan cloud confirms that stellar explosions occur outside the galaxy and allows us to study their shocks, stellar ejectors and environment,” they said. I said that.

“It will help us to better understand the evolution of the Magellan cloud and the history of interacting galaxies and their surrounding star formation.”

“We hope that new multi-wavelength investigations will reveal more supernova remnants around the Magellan cloud.”

“This new supernova remnants allows us to study the supernova explosions and the rest of the supernova evolution in low density and low metallic environments, and better serve to better the effects of metallicity on star formation and star evolution. I can understand it.”

result It will be displayed in the journal Astronomy and Astrophysics.

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Manamisasaki et al. 2025. The remains of a supernova on the outskirts of the large Magellan cloud. A&A 693, L15; doi: 10.1051/0004-6361/202452178

Source: www.sci.news

Mysterious X-ray oscillations detected in supermassive black hole by XMM-Newton

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In 2018, astronomers discovered that the corona of 1ES 1927+654, an actively accreting black hole with 1.4 million solar masses located in a galaxy some 270 million light-years away, suddenly disappeared and reassembled several months later. I observed that. The short but dramatic outage was the first of its kind in black hole astronomy. Now, astronomers using ESA's XMM-Newton Observatory have captured the same black hole exhibiting even more unprecedented behavior. They detected X-ray flashes from 1ES 1927+654 at a steadily increasing clip. Over a two-year period, the frequency of millihertz vibration flashes increased from every 18 minutes to every 7 minutes. This dramatic speed-up of X-rays has never been observed from a black hole before.

In this artist's concept, material is stripped from a white dwarf (bottom right sphere) orbiting within the innermost accretion disk surrounding the supermassive black hole of 1ES 1927+654. Image credit: NASA/Aurore Simonnet, Sonoma State University.

Black holes are a prediction of Albert Einstein's theory of general relativity. They are gravitational monsters that trap any matter or energy that crosses their “surface,” a region of spacetime known as the event horizon.

In its final descent into the black hole, a process known as accretion, the doomed material forms a disk around the black hole. The gas in the accretion disk heats up and emits primarily ultraviolet (UV) light.

The ultraviolet light interacts with the cloud of electrically charged gas or plasma that surrounds the black hole and accretion disk. This cloud is known as the corona, and the interaction energizes the ultraviolet light and amplifies it into X-rays, which can be captured by XMM Newton.

XMM-Newton has been observing 1ES 1927+654 since 2011. Back then, everything was very normal.

But things changed in 2018. As the X-ray corona disappeared, the black hole erupted in a massive explosion that seemed to disrupt its surroundings.

The coronavirus gradually returned, and by early 2021, it seemed like normal conditions had returned.

However, in July 2022, XMM Newton began observing its X-ray output fluctuating at a level of about 10% on timescales of 400 to 1,000 seconds.

This type of fluctuation, called quasi-periodic oscillations (QPO), is notoriously difficult to detect in supermassive black holes.

“This was the first sign that something strange was going on,” said Dr. Megan Masterson. Student at MIT.

The oscillations could suggest that a massive object, such as a star, is embedded in the accretion disk and rapidly orbiting the black hole on its way to being swallowed.

As an object approaches a black hole, the time it takes to orbit decreases and the frequency of its oscillations increases.

Calculations revealed that the orbiting object was probably the remains of a star known as a white dwarf, had about 0.1 times the mass of the Sun, and was moving at an astonishing speed.

It was completing one orbit of the central monster, covering a distance of about 100 million km, about every 18 minutes. Then things got even weirder.

Over nearly two years, XMM Newton showed an increase in the strength and frequency of the vibrations, but not as much as the researchers expected.

They assumed that an object's orbital energy is being emitted as gravitational waves, as prescribed by the theory of general relativity.

To test this idea, they calculated when the object crossed the event horizon, disappeared from view, and stopped oscillating. It turns out to be January 4, 2024.

“Never in my career have I been able to predict anything so accurately,” says Dr. Erin Kara of MIT.

In March 2024, XMM Newton observed it again and the oscillations were still present.

The object was currently traveling at about half the speed of light, completing an orbit every seven minutes.

Whatever was inside the accretion disk, it stubbornly refused to be swallowed up by the black hole.

Either something more than gravitational waves is at play, or the entire hypothesis needs to be changed.

Astronomers also considered other possibilities for the origin of the vibrations.

Remembering that the X-ray corona disappeared in 2018, they wondered if this cloud itself was vibrating.

The problem is that there is no established theory to explain such behavior, so there is no clear path to take this idea further, so they go back to the original model and realize there is a way to fix it. I did.

“If the black hole has a white dwarf companion, the gravitational waves produced by the black hole could be detected by LISA, an ESA mission scheduled to launch within the next 10 years in partnership with NASA.” said Masterson.

team's paper will appear in journal nature.

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Megan Masterson others. 2025. Millihertz oscillations near the innermost orbit of a supermassive black hole. naturein press. arXiv: 2501.01581

Source: www.sci.news

XMM-Newton discovers ultrafast black hole wind in Markarian 817

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Markarian 817 is the Seyfert 1 galaxy located 430 million light-years away in the constellation Draco. Also known as Mrk 817 or QSO J1436+5847, it hosts an active supermassive black hole of 81 million solar masses.

This artist's impression shows super-fast winds blowing from the center of the galaxy Markarian 817. These winds travel at millions of kilometers per hour and remove interstellar gas from vast regions of space. Without this gas, galaxies cannot form new stars, and the black holes at the galaxies' centers have little left to eat. The inset shows what is happening at the center of the galaxy. A supermassive black hole draws in gas from its surroundings to form a hot, brightly lit accretion disk (orange). The wind (white) is caused by a magnetic field within the disk, which causes particles to fly in all directions at incredibly high speeds. These winds effectively block the X-rays (blue) emitted by the extremely hot plasma surrounding the black hole, called the corona.Zack other. Using his X-ray telescope XMM-Newton at ESA, he captured Markarian 817 blowing out super-fast winds. This wind, which lasts for about a year, will have a major impact on star formation in the galaxy. The fact that black holes at the centers of galaxies exhibited fairly average activity levels before generating winds suggests that supervelocity black hole winds are much more common than previously thought. doing. In other words, black holes and their host galaxies strongly influence each other's evolution. Image credit: ESA / CC BY-SA 3.0 IGO.

At the center of every large galaxy is a supermassive black hole whose enormous gravitational pull pulls in gas from its surroundings.

As the gas spirals inward, it collects in a flat accretion disk around the black hole, where it heats up and glows.

Over time, the gas closest to the black hole passes the point of no return and gets swallowed up.

But black holes consume only a portion of the gas that swirls toward them.

While surrounding the black hole, some matter is bounced back into space, much like a messy toddler spilling everything on his plate.

In a more dramatic episode, a black hole turns the entire table upside down. The gas in the accretion disk is thrown off in all directions at such high velocities that it wipes out the surrounding interstellar gas.

This not only deprives the black hole of food, but also means that new stars cannot form over large areas and the structure of the galaxy changes.

Until now, this ultrafast black hole wind had only been detected as coming from a very bright accretion disk at the limit of its ability to pull in matter.

At this time, ESA's XMM-Newton spacecraft detected superfast winds in Markarian 817, a decidedly average galaxy that could be described as “just having a snack.”

“With the fans on the highest setting, we would expect very fast winds,” said Dr. Miranda Zak, an astronomer at the University of Michigan.

“In the galaxy we studied called Markarian 817, the fans were turned on at a lower power setting, but still produced incredibly energetic winds.”

“It is very rare to observe ultrafast winds, and even rarer to detect winds with enough energy to change the properties of the host galaxy.”

“The fact that Markarian 817 produced these winds for about a year, even though it was not particularly active, suggests that the black hole may have changed the shape of its host galaxy much more than previously thought. “This suggests that there is a sex,” said Roman astronomer Elias Cammun. Tre University.

Active galactic nuclei emit high-energy light, including X-rays. Markarian 817 stood out to astronomers because it was extremely quiet.

“The X-ray signal was so weak that I knew I was doing something wrong,” Zak said.

Follow-up observations using ESA's XMM Newton revealed what was actually happening. The superfast winds from the accretion disk acted like a shroud, blocking the X-rays emitted from the black hole's immediate surroundings.

These measurements were supported by observations made with NASA's NuSTAR telescope.

Detailed analysis of X-ray measurements revealed that Markarian 817's center did not send out a single puff of gas, but instead created a gust of wind storm over a wide area of ​​the accretion disk.

The winds lasted for hundreds of days and consisted of at least three distinct components, each traveling at a few percent of the speed of light.

This solves an unsolved puzzle in understanding how black holes and their surrounding galaxies interact with each other.

Many galaxies, including the Milky Way, appear to have large regions around their centers where few new stars form.

This could be explained by black hole winds sweeping away star-forming gas, but this works only if the winds are fast enough, persist long enough, and are produced by black holes at typical activity levels. limited to cases where

“One of the many unresolved problems in black hole research is the problem of achieving detection through long-term observations over many hours to capture important events,” said Dr. Norbert Schartel, a scientist on the XMM-Newton project. says.

“This highlights the paramount importance of the XMM-Newton mission into the future.”

“No other mission can achieve that combination of high sensitivity and the ability to make long, uninterrupted observations.”

a paper Regarding the survey results, Astrophysics Journal Letter.

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Miranda K. Zackother. 2024. Seyfert 1.2 Markarian 817 Hidden Sub-Eddington Feedback Intense Feedback.APJL 962, L1; doi: 10.3847/2041-8213/ad1407

Source: www.sci.news