Ferocious Wind Nebula Around Magnetar Observed for First Time

Giving us a rare, unique window into the environment and emission history of the strongest magnets in the cosmos

This X-ray image shows extended emission around a source known as Swift J1834.9-0846, a rare ultra-magnetic neutron star called a magnetar. The glow arises from a cloud of fast-moving particles produced by the neutron star and corralled around it. Color indicates X-ray energies, with 2,000-3,000 electron volts (eV) in red, 3,000-4,500 eV in green, and 5,000 to 10,000 eV in blue. The image combines observations by the European Space Agency's XMM-Newton spacecraft taken on March 16 and Oct. 16, 2014. Credits: ESA/XMM-Newton/Younes et al. 2016
This X-ray image shows extended emission around a source known as Swift J1834.9-0846, a rare ultra-magnetic neutron star called a magnetar. The glow arises from a cloud of fast-moving particles produced by the neutron star and corralled around it. Color indicates X-ray energies, with 2,000-3,000 electron volts (eV) in red, 3,000-4,500 eV in green, and 5,000 to 10,000 eV in blue. The image combines observations by the European Space Agency’s XMM-Newton spacecraft taken on March 16 and Oct. 16, 2014.
Credits: ESA/XMM-Newton/Younes et al. 2016

Space news (astrophysics: wind nebulas; Swift J1834.9-0846) – 13,000 light-years toward the constellation Scutum in the midst of a vast cloud of high-energy, particles surrounding supernova remnant W41 –

Astronomers studying the strongest magnets discovered during the human journey to the beginning of space and time, magnetars, have detected one they haven’t seen before. A magnetar, a rare highly magnetic neutron star with a vast cloud of high-energy, recently-emitted particles called a wind nebula streaming from it. Offering a unique window into the characteristics, environment and emission history of one of the most enigmatic and eye-opening objects ever detected.

“Right now, we don’t know how J1834.9 developed and continues to maintain a wind nebula, which until now was a structure only seen around young pulsars,” said lead researcher George Younes, a postdoctoral researcher at George Washington University in Washington. “If the process here is similar, then about 10 percent of the magnetar’s rotational energy loss is powering the nebula’s glow, which would be the highest efficiency ever measured in such a system.”

This illustration compares the size of a neutron star to Manhattan Island in New York, which is about 13 miles long. A neutron star is the crushed core left behind when a massive star explodes as a supernova and is the densest object astronomers can directly observe. Credits: NASA's Goddard Space Flight Center
This illustration compares the size of a neutron star to Manhattan Island in New York, which is about 13 miles long. A neutron star is the crushed core left behind when a massive star explodes as a supernova and is the densest object astronomers can directly observe.
Credits: NASA’s Goddard Space Flight Center

An object around 13 miles (20 kilometers) in diameter, or about the length of Manhattan Island, only 29 magnetars have been detected, so far. In this particular case, the source of detected emissions is called Swift J1834.9-0846, a rare type of ultra-magnetic neutron star detected by the Swift Gamma-ray Burst Satellite on August 7, 2011. It was subsequently looked at closer a month later by a team led by Younes using the European Space Agency’s (ESA) XMM-Newton X-ray Observatory. It was at this time astronomers realized and confirmed the first wind nebula ever detected around a magnetar.

“For me, the most interesting question is, why is this the only magnetar with a nebula? Once we know the answer, we might be able to understand what makes a magnetar and what makes an ordinary pulsar,” said co-author Chryssa Kouveliotou, a professor in the Department of Physics at George Washington University’s Columbian College of Arts and Sciences.

Neutron stars are the crushed cores of massive stars left over after they have gone supernova and the densest objects astrophysicists have been able to directly observe during the human journey to the beginning of space and time. All neutron star magnetic fields detected, so far, are 100 to 10 trillion times stronger than Earth’s, and magnetar fields reach levels thousands of times stronger. Astrophysicists have no ideas on how magnetic fields of such immense strength are formed. 

 co-author Alice Harding, an astrophysicist at NASA's Goddard Space Flight Center in Greenbelt, Maryland. Credits: NASA
Co-author Alice Harding, an astrophysicist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
Credits: NASA

“Making a wind nebula requires large particle fluxes, as well as some way to bottle up the outflow so it doesn’t just stream into space,” said co-author Alice Harding, an astrophysicist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “We think the expanding shell of the supernova remnant serves as the bottle, confining the outflow for a few thousand years. When the shell has expanded enough, it becomes too weak to hold back the particles, which then leak out and the nebula fades away. This naturally explains why wind nebulae are not found among older pulsars, even those driving strong outflows.

“The nebula around J1834.9 stores the magnetar’s energetic outflows over its whole active history, starting many thousands of years ago,” said team member Jonathan Granot, an associate professor in the Department of Natural Sciences at the Open University in Ra’anana, Israel. “It represents a unique opportunity to study the magnetar’s historical activity, opening a whole new playground for theorists like me.”

What’s next?

Astrophysicists think a magnetar outburst’s powered by energy stored in its super-strong magnetic field produced gamma rays and x-rays, along with the gales of accelerated particles making up the nebula wind detected in the case of Swift J1834.9-0846. Now, they have a mystery to figure out, and new theories to deduce to explain the way a magnetar produces a nebula wind. 

Learn about the plasma jets of active supermassive black holes.

Learn what astronomers have discovered about the distribution of common chemicals during the early moments of the cosmos.

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Learn more about neutron stars.

Read more about magnetars here.

Discover NASA’s Goddard Space Flight Center.

Learn more about the discoveries of NASA’s Swift Gamma-ray Burst Satellite here.

Read more about Swift J1834.9-0846.

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The Plasma Jets of Active Supermassive Black Holes

Transform surrounding regions and actively evolve host galaxies 

This artist's rendition illustrates a rare galaxy that is extremely dusty, and produces radio jets. Scientists suspect that these galaxies are created when two smaller galaxies merge. A few billion years after the Big Bang, astronomers suspect that small galaxies across the Universe regularly collided forcing the gas, dust, stars, and black holes within them to unite. The clashing of galactic gases was so powerful it ignited star formation, while fusing central black holes developed an insatiable appetite for gas and dust. With stellar nurseries and black holes hungry for galactic gas, a struggle ensued. Scientists say this struggle for resources is relatively short-lived, lasting only 10 to 100 million years. Eventually, much of the gas will be pushed out of the galaxy by the powerful winds of newborn stars, stars going supernovae (dying in a cataclysmic explosion), or radio jets shooting out of central supermassive black holes. The removal of gas will stunt the growth of black holes by "starving'' them, and quench star formation. They believe that these early merging structures eventually grew into some of the most massive galaxies in the Universe.
This artist’s rendition illustrates a rare galaxy that is extremely dusty and produces radio jets. Scientists suspect that these galaxies are created when two smaller galaxies merge.
A few billion years after the Big Bang, astronomers suspect that small galaxies across the Universe regularly collided forcing the gas, dust, stars, and black holes within them to unite. The clashing of galactic gasses was so powerful it ignited star formation while fusing central black holes developed an insatiable appetite for gas and dust. With stellar nurseries and black holes hungry for galactic gas, a struggle ensued.
Scientists say this struggle for resources is relatively short-lived, lasting only 10 to 100 million years. Eventually, much of the gas will be pushed out of the galaxy by the powerful winds of newborn stars, stars going supernovae (dying in a cataclysmic explosion), or radio jets shooting out of central supermassive black holes. The removal of gas will stunt the growth of black holes by “starving” them and quench star formation.
They believe that these early emerging structures eventually grew into some of the most massive galaxies in the Universe. Credits: NASA/JPL

Space news (astrophysics: spinning black holes; bigger, brighter plasma jets) – in the core of galaxies across the cosmos, observing the spin of supermassive black holes – 

In this radio image, two jets shoot out of the center of active galaxy Cygnus A. GLAST may solve the mystery of how these jets are produced and what they are made of. Credit: NRAO
In this radio image, two jets shoot out of the center of active galaxy Cygnus A. GLAST may solve the mystery of how these jets are produced and what they are made of. Credit: NRAO

Have you ever had the feeling the world isn’t the way you see it? That reality’s different than the view your senses offer you? The universe beyond the Earth is vast beyond comprehension and weird in ways human imagination struggles to fathom. Beyond the reach of your senses, the fabric of spacetime warps near massive objects, and even light bends to the will of gravity. In the twilight zone where your senses fear to tread, the cosmos twists and turns in weird directions and appears to leave the universe and reality far behind. Enigmas wrapped in cosmic riddles abound and mysteries to astound and bewilder the human soul are found. 

The galaxy NGC 4151 is located about 45 million light-years away toward the constellation Canes Venatici. Activity powered by its central black hole makes NGC 4151 one of the brightest active galaxies in X-rays. Credit: David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration. Credits: NASA/JPL
The galaxy NGC 4151 is located about 45 million light-years away toward the constellation Canes Venatici. Activity powered by its central black hole makes NGC 4151 one of the brightest active galaxies in X-rays. Credit: David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration. Credits: NASA/JPL

Imagine an object containing the mass of millions even billions of stars like the Sun. Squeeze that matter into a region of infinitely small volume, a region so dense the gravitational force it exerts warps spacetime and prevents even light from escaping its grasp. This object’s what astronomers call a supermassive black hole, a titanic monster your eyes can’t see with a gravitational pull that would stretch your body to infinity as you approached and crossed its outer boundary, the event horizon. Beyond this point, spacetime and reality take a turn toward the extreme, and the rules of science don’t apply. You have entered the realm of one of the most mysterious and enigmatic objects discovered during the human journey to the beginning of space and time.  

In the newly discovered type of AGN, the disk and torus surrounding the black hole are so deeply obscured by gas and dust that no visible light escapes, making them very difficult to detect. This illustration shows the scene from a more distant perspective than does the other image. Click on image for high-res version. Image credit: Aurore Simonnet, Sonoma State University.
In the newly discovered type of AGN, the disk and torus surrounding the black hole are so deeply obscured by gas and dust that no visible light escapes, making them very difficult to detect. This illustration shows the scene from a more distant perspective than does the other image. Click on image for high-res version. Image credit: Aurore Simonnet, Sonoma State University.

Astronomers hunting for supermassive black holes have pinpointed their realms to be the center of massive galaxies and even the center of galaxy clusters. From this central location in each galaxy, the gravitational well of each supermassive black hole appears to act as an anchor point for the billions of stars within, and astronomers believe a force for change and evolution of every galaxy and galaxy cluster in which they exist. Surrounded and fed by massive clouds of gas and matter called accretion disks, with powerful particle jets streaming from opposite sides like the death ray in Star Wars, fierce, hot winds sometimes moving at millions of miles per hour blow from these supermassive monsters in all directions. 

These galaxy clusters show that younger, more distant galaxy clusters contained far more active galactic nuclei (AGN) than older, nearby ones. It was found that the clusters at 58% of the Universe's current age contained about 20 times more AGN than those at 82% of Universe's age. The galaxies in the earlier Universe contained much more gas that allowed for more star formation and black hole growth. In the Chandra X-ray images, red, green, and blue represent low, medium, and high-energy X-rays.
These galaxy clusters show that younger, more distant galaxy clusters contained far more active galactic nuclei (AGN) than older, nearby ones. It was found that the clusters at 58% of the Universe’s current age contained about 20 times more AGN than those at 82% of Universe’s age. The galaxies in the earlier Universe contained much more gas that allowed for more star formation and black hole growth. In the Chandra X-ray images, red, green, and blue represent low, medium, and high-energy X-rays. Credits: NASA/Chandra

“A lot of what happens in an entire galaxy depends on what’s going on in the minuscule central region where the black hole lies,” said theoretical astrophysicist David Garofalo of NASA’s Jet Propulsion Laboratory in Pasadena, Calif. Garofalo is the lead author of a new paper that appeared online May 27 in the Monthly Notices of the Royal Astronomical Society. Other authors are Daniel A. Evans of the Massachusetts Institute of Technology, Cambridge, Mass., and Rita M. Sambruna of NASA Goddard Space Flight Center, Greenbelt, Md. 

These galaxy clusters show that younger, more distant galaxy clusters contained far more active galactic nuclei (AGN) than older, nearby ones. It was found that the clusters at 58% of the Universe's current age contained about 20 times more AGN than those at 82% of Universe's age. The galaxies in the earlier Universe contained much more gas that allowed for more star formation and black hole growth. In the Chandra X-ray images, red, green, and blue represent low, medium, and high-energy X-rays.
These galaxy clusters show that younger, more distant galaxy clusters contained far more active galactic nuclei (AGN) than older, nearby ones. It was found that the clusters at 58% of the Universe’s current age contained about 20 times more AGN than those at 82% of Universe’s age. The galaxies in the earlier Universe contained much more gas that allowed for more star formation and black hole growth. In the Chandra X-ray images, red, green, and blue represent low, medium, and high-energy X-rays. Credits: NASA/Chandra

Astronomers studying powerful particle jets streaming from supermassive black holes use to think these monsters spin either in the same direction as their accretion disks, called prograde black holes, or against the flow, retrograde black holes. For the past few decades, Garofalo and team have worked with a theory that the faster the spin of a black hole, the more powerful the particle jets streaming from it. Unfortunately, anomalies in the form of some prograde black holes with no jets have been discovered. This has scientists turning their ideas upside down and sideways, to see if flipping their “spin paradigm” model on its head explains recent anomalies in the theory. 

This composite image shows a vast cloud of hot gas (X-ray/red), surrounding high-energy bubbles (radio/blue) on either side of the bright white area around the supermassive black hole. By studying the inner regions of the galaxy with Chandra, scientists estimated the rate at which gas is falling toward the galaxy's supermassive black hole. These data also allowed an estimate of the power required to produce the bubbles, which are each about 10,000 light years in diameter. Surprisingly, the analysis indicates that most of the energy released by the infalling gas goes into producing jets of high-energy particles that create the huge bubbles, rather than into an outpouring of light as observed in many active galactic nuclei.
This composite image shows a vast cloud of hot gas (X-ray/red), surrounding high-energy bubbles (radio/blue) on either side of the bright white area around the supermassive black hole. By studying the inner regions of the galaxy with Chandra, scientists estimated the rate at which gas is falling toward the galaxy’s supermassive black hole. These data also allowed an estimate of the power required to produce the bubbles, which are each about 10,000 light years in diameter. Surprisingly, the analysis indicates that most of the energy released by the infalling gas goes into producing jets of high-energy particles that create the huge bubbles, rather than into an outpouring of light as observed in many active galactic nuclei. X-ray: NASA/CXC/KIPAC/S.Allen et al; Radio: NRAO/VLA/G.Taylor; Infrared: NASA/ESA/McMaster Univ./W.Harris

Using data collected during a more recent study that links their previous theory with observations of galaxies at varying distances from Earth across the observable universe. Astronomers found more distant radio-loud galaxies with jets are powered by retrograde black holes, while closer radio-quiet black holes have prograde black holes. The study showed supermassive black holes found at the core of galaxies evolve over time from a retrograde to prograde state.  

This illustration shows the different features of an active galactic nucleus (AGN), and how our viewing angle determines what type of AGN we observe. The extreme luminosity of an AGN is powered by a supermassive black hole at the center. Some AGN have jets, while others do not. Click on image for unlabeled, high-res version. Image credit: Aurore Simonnet, Sonoma State University.
This illustration shows the different features of an active galactic nucleus (AGN), and how our viewing angle determines what type of AGN we observe. The extreme luminosity of an AGN is powered by a supermassive black hole at the center. Some AGN have jets, while others do not. Click on image for unlabeled, high-res version. Image credit: Aurore Simonnet, Sonoma State University.

“This new model also solves a paradox in the old spin paradigm,” said David Meier, a theoretical astrophysicist at JPL not involved in the study. “Everything now fits nicely into place.” 

A mere 11 million light-years away, Centaurus A is a giant elliptical galaxy - the closest active galaxy to Earth. This remarkable composite view of the galaxy combines image data from the x-ray ( Chandra), optical(ESO), and radio(VLA) regimes. Centaurus A's central region is a jumble of gas, dust, and stars in optical light, but both radio and x-ray telescopes trace a remarkable jet of high-energy particles streaming from the galaxy's core. The cosmic particle accelerator's power source is a black hole with about 10 million times the mass of the Sun coincident with the x-ray bright spot at the galaxy's center. Blasting out from the active galactic nucleus toward the upper left, the energetic jet extends about 13,000 light-years. A shorter jet extends from the nucleus in the opposite direction. Other x-ray bright spots in the field are binary star systems with neutron stars or stellar mass black holes. Active galaxy Centaurus A is likely the result of a merger with a spiral galaxy some 100 million years ago.
A mere 11 million light-years away, Centaurus A is a giant elliptical galaxy – the closest active galaxy to Earth. This remarkable composite view of the galaxy combines image data from the x-ray ( Chandra), optical(ESO), and radio(VLA) regimes. Centaurus A’s central region is a jumble of gas, dust, and stars in optical light, but both radio and x-ray telescopes trace a remarkable jet of high-energy particles streaming from the galaxy’s core. The cosmic particle accelerator’s power source is a black hole with about 10 million times the mass of the Sun coincident with the x-ray bright spot at the galaxy’s center. Blasting out from the active galactic nucleus toward the upper left, the energetic jet extends about 13,000 light-years. A shorter jet extends from the nucleus in the opposite direction. Other x-ray bright spots in the field are binary star systems with neutron stars or stellar mass black holes. Active galaxy Centaurus A is likely the result of a merger with a spiral galaxy some 100 million years ago. Credits: X-ray – NASA, CXC, R.Kraft (CfA), et al.; Radio – NSF, VLA, M.Hardcastle (U Hertfordshire) et al.; Optical – ESO, M.Rejkuba (ESO-Garching) et al.

Astrophysicists studying backward spinning black holes believe more powerful particle jets stream from these supermassive black holes because additional space exists between the monster and the inner edge of the accretion disk. This additional space between the monster and accretion disk provides more room for magnetic fields to build-up, which fuels the particle jet and increases its power. This idea is known as Reynold’s Conjecture, after the theoretical astrophysicist Chris Reynolds of the University of Maryland, College Park. 

The optical counterparts of many active galactic nuclei (circled) detected by the Swift BAT Hard X-ray Survey clearly show galaxies in the process of merging. These images, taken with the 2.1-meter telescope at Kitt Peak National Observatory in Arizona, show galaxy shapes that are either physically intertwined or distorted by the gravity of nearby neighbors. These AGN were known prior to the Swift survey, but Swift has found dozens of new ones in more distant galaxies. Credit: NASA/Swift/NOAO/Michael Koss and Richard Mushotzky (Univ. of Maryland)
The optical counterparts of many active galactic nuclei (circled) detected by the Swift BAT Hard X-ray Survey clearly show galaxies in the process of merging. These images, taken with the 2.1-meter telescope at Kitt Peak National Observatory in Arizona, show galaxy shapes that are either physically intertwined or distorted by the gravity of nearby neighbors. These AGN were known prior to the Swift survey, but Swift has found dozens of new ones in more distant galaxies. Credit: NASA/Swift/NOAO/Michael Koss and Richard Mushotzky (Univ. of Maryland)

“If you picture yourself trying to get closer to a fan, you can imagine that moving in the same rotational direction as the fan would make things easier,” said Garofalo. “The same principle applies to these black holes. The material orbiting around them in a disk will get closer to the ones that are spinning in the same direction versus the ones spinning the opposite way.”  

Swift's Hard X-ray Survey offers the first unbiased census of active galactic nuclei in decades. Dense clouds of dust and gas, illustrated here, can obscure less energetic radiation from an active galaxy's central black hole. High-energy X-rays, however, easily pass through. Credit: ESA/NASA/AVO/Paolo Padovani
Swift’s Hard X-ray Survey offers the first unbiased census of active galactic nuclei in decades. Dense clouds of dust and gas, illustrated here, can obscure less energetic radiation from an active galaxy’s central black hole. High-energy X-rays, however, easily pass through. Credit: ESA/NASA/AVO/Paolo Padovani

Scientists believe the powerful particle jets and winds emanating from supermassive black holes found at the center of galaxies also play a key role in shaping their evolution and eventual fate. Often even slowing the formation rate of new stars in a host galaxy and nearby island universes as well.  

“Jets transport huge amounts of energy to the outskirts of galaxies, displace large volumes of the intergalactic gas, and act as feedback agents between the galaxy’s very center and the large-scale environment,” said Sambruna. “Understanding their origin is of paramount interest in modern astrophysics.” 

What lies just beyond the reach of our senses and technology, beneath the exterior of these supermassive black holes? Scientists presently study these enigmatic stellar objects looking for keys to the doors of understanding beyond the veil of gas and dust surrounding these titanic beasts. Keys they hope one day to use to unlock even greater secrets of reality just beyond hidden doors of understanding.  

Watch this video on active galactic nuclei.

Read and learn more about the supermassive black holes astronomers detect in a region called the COSMOS field.

Read about the recent detection by astronomers of read-end collisions between knots in the particle jets of supermassive black holes.

Learn what astronomers have discovered about feedback mechanisms in the feeding processes of active supermassive black holes.

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Binary Star System V404 Cygni Flares to Life

Forming rings of X-ray light that expand with time, creating a shooting target effect 

rings_full
Rings of X-ray light centered on V404 Cygni, a binary system containing an erupting black hole (dot at center), were imaged by the X-ray Telescope aboard NASA’s Swift satellite from June 30 to July 4. A narrow gap splits the middle ring in two. Color indicates the energy of the X-rays, with red representing the lowest (800 to 1,500 electron volts, eV), green for medium (1,500 to 2,500 eV), and the most energetic (2,500 to 5,000 eV) shown in blue. For comparison, visible light has energies ranging from about 2 to 3 eV. The dark lines running diagonally through the image are artifacts of the imaging system. Credits: Andrew Beardmore (Univ. of Leicester) and NASA/Swift

Space news (astrophysics: binary star systems; black hole/sun-like star systems) – 8,000 light-years away toward the constellation Cygnus, next to flaring 10 solar mass black hole – 

It all started just before 2:32 p.m. on June 15, 2015, when NASA’s Swift X-ray Burst Alert Satellite detected a rising wave of high-speed, extremely-energetic X-rays emanating from the direction of the constellation Cygnus. Additional detections of the same flare ten minutes later by a Japanese experiment on the International Space Station called the Monitor of All-sky X-ray Image (MAXI) and other detectors. Allowed astronomers to determine the outburst detected originated 8,000 light-years away in low-mass X-ray binary V404 Cygni, where previous data indicated a stellar-mass black hole and sun-like star orbited each other. A black hole and sun-like star binary system that up to this point had been sleeping since its last outburst in 1989. 

moon_v404cyg_comp
The Swift X-ray image of V404 Cygni covers a patch of the sky equal to about half the apparent diameter of the full moon. This image shows the rings as they appeared on June 30. Credits: NASA’s Scientific Visualization Studio (left), Andrew Beardmore (Univ. of Leicester); NASA/Swift (right)

Fifteen days later on June 30, a team of scientists from around the world led by Andrew Beardmore of the University of Leicester in the United Kingdom investigated V404 Cygni a little closer using NASA’s Swift X-ray Burst Alert Satellite. Images taken (above) revealed a series of concentric rings of X-ray light centered on a 10 solar mass black hole (dot at the center of image). 

On the left, an optical image from the Digitized Sky Survey shows Cygnus X-1, outlined in a red box. Cygnus X-1 is located near large active regions of star formation in the Milky Way, as seen in this image that spans some 700 light years across. An artist's illustration on the right depicts what astronomers think is happening within the Cygnus X-1 system. Cygnus X-1 is a so-called stellar-mass black hole, a class of black holes that comes from the collapse of a massive star. The black hole pulls material from a massive, blue companion star toward it. This material forms a disk (shown in red and orange) that rotates around the black hole before falling into it or being redirected away from the black hole in the form of powerful jets.
On the left, an optical image from the Digitized Sky Survey shows Cygnus X-1, outlined in a red box. Cygnus X-1 is located near large active regions of star formation in the Milky Way, as seen in this image that spans some 700 light years across. An artist’s illustration on the right depicts what astronomers think is happening within the Cygnus X-1 system. Cygnus X-1 is a so-called stellar-mass black hole, a class of black holes that comes from the collapse of a massive star. The black hole pulls material from a massive, blue companion star toward it. This material forms a disk (shown in red and orange) that rotates around the black hole before falling into it or being redirected away from the black hole in the form of powerful jets.

Astronomers believe the x-ray rings are the result of echoing x-ray light from a large flare on June 26, 2016, at 1:40 p.m. EDT. The flare emitted x-rays in all directions. Multiple dust layers at around 4,000 and 1,000 light-years from V404 Cygni reflected some of these x-rays towards Earth. This reflected light travels a greater distance and reaches us slightly later than light traveling a straighter path. The small time difference produced an x-ray echo, formed x-ray rings expanding in spacetime.  

“The flexible planning of Swift observations has given us the best dust-scattered X-ray ring images ever seen,” Beardmore said. “With these observations, we can make a detailed study of the normally invisible interstellar dust in the direction of this black hole.” 

What’s next?

The team is currently watching V404 Cygni, waiting for its next outburst, and preparing Swift to collect additional data to determine exactly what’s going on here. They hope to hit the bulls eye in human understanding of the collection on x-ray sources detected across the cosmos. Regular monitoring of this binary system using a suite of telescopes and instruments could give us clues to how a stellar-mass black hole and sun-like star end up orbiting each other. About the origin and formation of the unusual types of binary systems detected during the human journey to the beginning of space and time. 

Watch this YouTube video on the flaring of V404 Cygni.

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Hubble Finds Youngest, Nearby Black Hole Candidate

Characteristics of 30-year old supernova remnant SN 1979C are consistent with predicted theory on birth of black hole or possibly a rapidly spinning neutron star

•If SN 1979C does indeed contain a black hole, it will give astronomers a chance to learn more about which stars make black holes and which create neutron stars. Image: NASA/Chandra
Far away in galaxy M100 we search for black holes. If SN 1979C does indeed contain a black hole, it will give astronomers a chance to learn more about which stars make black holes and which create neutron stars.
Image: NASA/Chandra

Space news (December 11, 2015) – 50 million light-years from Earth, in galaxy M100 –

One of the most enigmatic cosmic objects discovered during the human journey to the beginning of space and time, black holes continue to entrance and mystify both astronomers studying them and common people trying to imagine the possibility of such monsters existing. Black holes are also one of the most difficult celestial objects to detect since not even light rays can escape from the strength of their gravitational-embrace, once they travel beyond the imaginary point-of-no-return astronomers call the “event horizon” of a black hole.

Astronomers working with NASA’s Chandra X-ray Observatory, after analysis of additional data provided by NASA’s Swift Gamma-ray Burst Explorer, the European Space Agency’s XMM-Newton spacecraft, and German’s ROSAT Observatory, believe they have evidence to suggest 30-year old supernova remnant SN 1979C could be a black hole.

NASA and German ROSAT Observatory scans the x-ray sky.
The ROSAT Observatory scans the x-ray sky looking for supernovas that could have given birth to a black hole. Image: NASA.

Supernova remnant SN 1979C shined X-rays steadily during constant observation from 1995 to 2007. This suggests to astronomers either a black hole eating material left over from the supernova or a hidden binary companion feeding hot material to the monster hidden within 

“If our interpretation is correct, this is the nearest example where the birth of a black hole has been observed,” said Daniel Patnaude of the Harvard-Smithsonian Center for Astrophysics in Cambridge, Mass. who led the study.

Astronomers have detected new black holes that existed during the ancient past through gamma-ray bursts (GRBs) associated with them. SN 1979C is listed in a class of supernovae not expected to produce GRBs, which theory predicts could be the most common way to make a black hole.   

This may be the first time the common way of making a black hole has been observed,” said co-author Abraham Loeb, also of the Harvard-Smithsonian Center for Astrophysics. “However, it is very difficult to detect this type of black hole birth because decades of X-ray observations are needed to make the case.

The idea SN 1979C is a young, recently-formed black hole made from the remnants of a star with 20 times the mass of Sol, that went supernova some thirty Earth-years ago, is consistent with present theory. In 2005, a theory was put forth claiming the bright source of X-rays detected steaming from the supernova remnant is powered by a jet emanating from the monster that’s unable to penetrate the thick hydrogen envelope surrounding it.

Astronomers think there could be one other possibility for the identity of SN 1979C. It could be a rapidly spinning neutron star, with an extremely powerful wind of high energy particles. Present theory predicts this would produce the bright X-ray emissions detected during 12 years of constant observation. 

If this is true, this would make this supernova remnant the youngest known example of a celestial object called a pulsar wind nebula. The Crab Nebula is the best-known example of a bright pulsar wind nebula, but we would have to go back over 900 years to view it as a 30-year old. SN 1979C is a lot younger, which is a great opportunity to study one of the most enigmatic, yet difficult to detect celestial objects viewed during the human journey to the beginning of space and time.

It’s very rewarding to see how the commitment of some of the most advanced telescopes in space, like Chandra, can help complete the story,” said Jon Morse, head of the Astrophysics Division at NASA’s Science Mission Directorate.

Jon Morse is a pioneer, leader and hero of the human journey to the beginning of space and time
Jon Morse is a pioneer, leader and hero of the human journey to the beginning of space and time. Image: Space.com.

Study continues

Astronomers will now continue to study SN 1979C, to see if they can determine its identity. No matter it’s true identity or nature, we can expect this celestial object to be one of the most studied examples of a young supernova remnant during recent times. 

You can learn more about black holes here.

Discover the journey of NASA’s Chandra X-ray Observatory here.

Learn more about NASA’s Marshall Space Flight Center here.

Learn about the mission of the Harvard-Smithsonian Center for Astrophysics here.

Take NASA’s journey through space history here.

Learn about NASA’s Swift Gamma-ray Burst Explorer here.

Take the journey of the European Space Agency’s XMM-Newton spacecraft here.

Discover German’s ROSAT Observatory here.

Learn about hydrocarbon dunes detected by NASA’s Cassini spacecraft on Saturn’s frozen moon Titan.

Read about the Monster of the Milky Way as it comes to life.

Learn how astronomers study a galactic nursery using the Hubble Space Telescope.

NASA WISE and Spitzer Telescopes Discover Titanic Galaxy Cluster

Astronomers say this monster was one of the biggest galaxy clusters of its time

The galaxy cluster called MOO J1142+1527 can be seen here as it existed when light left it 8.5 billion years ago. The red galaxies at the center of the image make up the heart of the galaxy cluster. Credits: NASA/JPL-Caltech/Gemini/CARMA
The galaxy cluster called MOO J1142+1527 can be seen here as it existed when light left it 8.5 billion years ago. The red galaxies at the center of the image make up the heart of the galaxy cluster.
Credits: NASA/JPL-Caltech/Gemini/CARMA

Space news (November 07, 2015) – 8.5 billion light-years away in a remote part of the cosmos –

NASA astronomers conducting a survey of galaxy clusters using the Spitzer Space Telescope and Wide-field Infrared Survey Explorer (WISE) recently viewed one of the biggest galaxy clusters ever recorded. Called Massive Overdense Object (MOO) J1142+1527, this monster galaxy cluster is in a very distant part of the universe and existed around 4 billion years before the birth of Earth.

8.5 billion years have passed since the light seen in the image above reached us here on Earth. MOO J1142+1527 has grown bigger during this time as more galaxies were drawn into the cluster and become even more extreme as far as galaxy clusters go. Containing thousands of galaxies, each with hundreds of billions of individual suns, galaxy clusters like this are some of the biggest structures in the cosmos. 

It’s the combination of Spitzer and WISE that lets us go from a quarter billion objects down to the most massive galaxy clusters in the sky,” said Anthony Gonzalez of the University of Florida in Gainesville, lead author of a new study published in the Oct. 20 issue of the Astrophysical Journal Letters.

Based on our understanding of how galaxy clusters grow from the very beginning of our universe, this cluster should be one of the five most massive in existence at that time,” said co-author Peter Eisenhardt, the project scientist for WISE at NASA’s Jet Propulsion Laboratory in Pasadena, California.

Astronomers conducting this survey will now spend the next year sifting through more than 1,700 more galaxy clusters detected by the combined power of NASA’s Spitzer Space Telescope and Wide-field Infrared Survey Explorer looking for the largest galaxy clusters in the cosmos. Once they find the biggest galaxy clusters in the universe, they’ll use the data obtained to investigate their evolution and the extreme environments they’re found.

Once we find the most massive clusters, we can start to investigate how galaxies evolved in these extreme environments,” said Gonzalez.

You can learn more about the mission of the Spitzer Space Telescope here.

Discover the voyage and discoveries of WISE here.

Learn more about galaxy clusters here.

Read about the space missions of NASA here.

Learn more about the final days of stars.

Read about the Little Gem Nebula.

Read about plans for man to travel to Mars in the decades ahead.

Astronomers Discover Disks Surrounding Supermassive Black Holes Emit X-ray Flares when Corona is Ejected

But why is the Corona ejected?

Astronomers believe high energy particles, the corona, of supermassive black holes can create the massive X-ray flares viewed. Image credit. Jet Propulsion Laboratory.
Astronomers believe high energy particles, the corona, of supermassive black holes can create the massive X-ray flares viewed. Image credit. Jet Propulsion Laboratory.

Space news (November 02, 2015) – 

Bizarre and mysterious stellar objects, studying black holes keeps astronomers up all night. One of the more puzzling mysteries of these unique objects are gigantic flares of X-rays (relativistic jets) detected erupting from disks of hot, glowing dust surrounding them. X-ray flares astronomers are presently studying in order to better understand these enigmatic, yet strangely attractive stellar objects.

Astronomers observing supermassive black holes using NASA’s Swift spacecraft and Nuclear Spectroscopic Telescope Array (NuSTAR) recently caught one in the middle of a gigantic X-ray flare. After analysis, they discovered this particular flare appeared to be a result of the Corona surrounding the supermassive black hole – region of highly energetic particlesbeing launched into space. A result making scientists and astronomers rethink their theories on how relativistic jets are created and sustained.

This result suggests to scientists that supermassive black holes emit X-ray flares when highly energized particles (Coronas) are launched away from the black hole. In this particular case, X-ray flares traveling at 20 percent of the speed of light, and directly pointing toward Earth. The ejection of the Corona caused the X-ray light emitted to brighten a little in an effect called relativistic Doppler boosting. This slightly brighter X-ray light has a different spectrum due to the motion of the Corona, which helped astronomers detect this unusual phenomenon leaving the disk of dust and gas surrounding this supermassive black hole.

This is the first time we have been able to link the launching of the Corona to a flare,” said Dan Wilkins of Saint Mary’s University in Halifax, Canada, lead author of a new paper on the results appearing in the Monthly Notices of the Royal Astronomical Society. “This will help us understand how supermassive black holes power some of the brightest objects in the universe.

Astronomers currently propose two different scenarios for the source of coronas surrounding supermassive black holes. The “lamppost” scenario indicates coronas are analogous to light bulbs sitting above and below the supermassive black hole along its axis of rotation. This idea proposes coronas surrounding supermassive black holes are spread randomly as a large cloud or a “sandwich” that envelopes the disk of dust and material surrounding the black hole. Some astronomers think coronas surrounding supermassive black holes could alternate between both the lamppost and sandwich configurations.

The latest data seems to lean toward the “lamppost” scenario and gives us clues to how the coronas surrounding black holes move. More observations are needed to ascertain additional facts concerning this unusual phenomenon and how massive X-ray flares and gamma rays emitted by supermassive black holes are created.

Something very strange happened in 2007, when Mrk 335 faded by a factor of 30. What we have found is that it continues to erupt in flares but has not reached the brightness levels and stability seen before,” said Luigi Gallo, the principal investigator for the project at Saint Mary’s University. Another co-author, Dirk Grupe of Morehead State University in Kentucky, has been using Swift to regularly monitor the black hole since 2007.

The Corona gathered inward at first and then launched upwards like a jet,” said Wilkins. “We still don’t know how jets in black holes form, but it’s an exciting possibility that this black hole’s Corona was beginning to form the base of a jet before it collapsed.”

The nature of the energetic source of X-rays we call the Corona is mysterious, but now with the ability to see dramatic changes like this we are getting clues about its size and structure,” said Fiona Harrison, the principal investigator of NuSTAR at the California Institute of Technology in Pasadena, who was not affiliated with the study.

Study continues

Astronomers will now continue their study of supermassive black holes in the cosmos in order to remove the veil of mystery surrounding the X-ray flares they emit and other bizarre mysteries surrounding these enigmatic stellar objects. In particular, they would love to discover the reasons for the ejection of Coronas surrounding black holes.

You can learn more about black holes here.

Discover the Swift spacecraft here.

Take the voyage of NASA’s NuSTAR spacecraft here.

Take part in NASA’s mission to the stars here.

Read about ripples in the spacetime astronomers detected moving across the planet-making region of AU Microscopii.

Learn more about climatic collisions between galaxy clusters.

Read about NASA and its partners plans to travel to Mars for an extended stay in the next few decades.

The Monster of the Milky Way Comes to Life

Erupting X-ray flares every day, a ten-fold increase in bright flares from previous observations of Sagittarius A

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Astronomers believe the ten-fold increase in X-ray flares during the past year could be connected to the passage of a mysterious object designated G2 near the supermassive black hole (Image credit NASA and ESO

Space news (October 01, 2015) – 26,000 light-years from Earth, near the center of the Milky Way

NASA's Chandra X-ray Observatory is part of a new breed of star hunting telescopes.
NASA’s Chandra X-ray Observatory is part of a new breed of star hunting telescopes.

Astrophysicists combining the telescopic talents of NASA’s Chandra X-ray Observatory and Swift spacecraft, with the European Space Agency’s X-ray Space Observatory XMM-Newton, recently detected an increase in X-ray flares erupting from the supermassive black hole (Sagittarius A) at the center of the Milky Way.

NASA's Swift Gamma Ray Burst Explorer scans the universe looking for gamma ray bursts.
NASA’s Swift Gamma Ray Burst Explorer scans the universe looking for gamma ray bursts.

By analyzing data collected during extensive periods of monitoring by all three spacecraft, space scientists determined the Monster of the Milky Way – the supermassive black hole at the center with more than 4 million times the mass of Sol– has been more active during the past 15 years than first thought. 

An artists impression of the ESO's Newton XMM-Newton telescope.
An artists impression of the ESO’s Newton XMM-Newton telescope.

Erupting a bright X-ray flare every ten days, the Monster of the Milky Way has been eating hot gas falling into its gravity pool. Even more interesting, Sagittarius A during the past year has been erupting ten times as much, producing a bright X-ray flare every day. A discovery that has astrophysicists going over the data looking for a reason for the sudden increase. 

“For several years, we’ve been tracking the X-ray emission from Sgr A*. This includes also the close passage of this dusty object” said Gabriele Ponti of the Max Planck Institute for Extraterrestrial Physics in Germany. “A year or so ago, we thought it had absolutely no effect on Sgr A*, but our new data raise the possibility that that might not be the case.”

The mystery started late in 2013, as G2 passed close to the supermassive black hole. At this time, there wasn’t any apparent change in G2 as it approached Sagittarius A, other than being slightly stretched by the gravity pool of the black hole.

Originally astronomers thought G2 was a stretched cloud of gas and dust, but this finding has led scientists to the possibility it could be a dense body embedded in a dusty cocoon. Currently, there’s no consensus among astronomers on the identity of this mysterious object. But the recent ten-fold increase in X-ray flares as G2 passed near the supermassive black hole suggests there could be a connection of some kind. 

“There isn’t universal agreement on what G2 is,” said Mark Morris of the University of California at Los Angeles. “However, the fact that Sgr A* became more active not long after G2 passed by suggests that the matter coming off of G2 might have caused an increase in the black hole’s feeding rate.”

At this point, astronomers don’t know if the increase in X-ray flares from the supermassive black hole is common or unusual in nature. These emissions could be part of the normal life cycle of supermassive black holes and totally unrelated to the passage of G2. The ten-fold increase in X-ray flares could also be due to changing solar winds from nearby massive stars feeding gas and dust into the black hole.

What’s next?

Scientists will keep observing Sagittarius A over the next little while to see what pops up next in this mystery. Hopefully, they can shed some light on the reason the Monster of the Milky Way, suddenly started emitting X-ray flares once a day.  

“It’s too soon to say for sure, but we will be keeping X-ray eyes on Sgr A* in the coming months,” said co-author Barbara De Marco, also of Max Planck. “Hopefully, new observations will tell us whether G2 is responsible for the changed behavior or if the new flaring is just part of how the black hole behaves.”

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Discover the Butterfly Nebula or Twin Jet Nebula.

You can learn more about NASA’s Chandra X-ray Observatory here.

Learn more about the discoveries made by NASA’s Swift spacecraft here.

Discover the European Space Agency’s X-ray Space Observatory XMM-Newton here.

Learn more about the Monster of the Milky Way: Sagittarius A here.

Discover NASA’s mission to the stars here.

Take part in the European Space Agency’s mission to the stars here.

Watch this Nova video on the Monster of the Milky Way.