X-ray Light Source CX330 Detected in Bulge of Milky Way

Most isolated young star discovered launching jets of material into surrounding gas and dust

An unusual celestial object called CX330 was first detected as a source of X-ray light in 2009. It has been launching “jets” of material into the gas and dust around it. Credits: NASA/JPL-Caltech
An unusual celestial object called CX330 was first detected as a source of X-ray light in 2009. It has been launching “jets” of material into the gas and dust around it.
Credits: NASA/JPL-Caltech

Space news (astrophysics: massive, young stars in star-forming regions; unusual, isolated young star baffles astronomers) – approximately 27,000 light-years from Earth in an isolated region of the bulge of the Milky Way – 

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NASA’s Chandra X-ray Observatory first detected unusual stellar object CX330. Credits: NASA/Chandra

Astronomers surveying the universe looking for unusual celestial objects to study to add to human knowledge and understanding have found something they haven’t seen before. Unusual celestial object CX 330 was first noticed in data obtained during a survey of the bulge of the Milky Way in 2009 by NASA’s Chandra X-ray Observatory as a source of X-ray light. Additional observations of the source showed it also emitted light in optical wavelengths, but with so few clues to go on, astronomers had no idea what they were looking at. 

During more recent observations of CX 330 during August of 2015, astronomers discovered it had recently been active, launching jets of material into gas and dust surrounding it. During a period from 2007 to 2010, it had increased in brightness by hundreds of times, which made scientists curious to examine previous data obtained from the same region of the bulge. 

Using the unique orbit of NASA's Spitzer Space Telescope and a depth-perceiving trick called parallax, astronomers have determined the distance to an invisible Milky Way object called OGLE-2005-SMC-001. This artist's concept illustrates how this trick works: different views from both Spitzer and telescopes on Earth are combined to give depth perception. Credits: NASA/Spitzer
Using the unique orbit of NASA’s Spitzer Space Telescope and a depth-perceiving trick called parallax, astronomers have determined the distance to an invisible Milky Way object called OGLE-2005-SMC-001. This artist’s concept illustrates how this trick works: different views from both Spitzer and telescopes on Earth are combined to give depth perception. Credits: NASA/Spitzer

Looking at data obtained by NASA’s Wide-field Infrared Survey Explorer (WISE) in 2010, they realized the surrounding gas and dust was heated to the point of ionization.  Comparing this data to observations taken with NASA’s Spitzer Space Telescope in 2007, astronomers determined they were looking at a young star in an outburst phase, forming in an isolated region of the cosmos.

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Chris Britta Credits: Texas Tech University

“We tried various interpretations for it, and the only one that makes sense is that this rapidly growing young star is forming in the middle of nowhere,” said Chris Britta postdoctoral researcher at Texas Tech University in Lubbock, and lead author of a study on CX330 recently published in the Monthly Notices of the Royal Astronomical Society.

By combining this data with observations taken by a variety of both ground and space-based telescopes they were able to get an even clearer picture of CX330. An object very similar to FU Orionis, but likely more massive, compact, and hotter, and lying in a less populated region of space. Launched faster jets of outflow that heated a surrounding disk of gas and dust to the point of ionization, and increased the flow of material falling onto the star.

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Tom Maccarone Credits: Texas Tech University

“The disk has probably heated to the point where the gas in the disk has become ionized, leading to a rapid increase in how fast the material falls onto the star,” said Thomas Maccarone, study co-author and associate professor at Texas Tech.

The fact CX 330 lies in an isolated region of space, unlike the previous nine examples of this type of star observed during the human journey to the beginning of space and time, tweaks the interest of astronomers. The other nine examples all lie in star-forming regions of the Milky Way galaxy with ample material for new stars to form from, but the closest star-forming region to this young star is over 1,000 light-years away.

Joel Green Credits: NASA/Space Telescope Science Institute
Joel Green Credits: NASA/Space Telescope Science Institute

“CX330 is both more intense and more isolated than any of these young outbursting objects that we’ve ever seen,” said Joel Green, study co-author and researcher at the Space Telescope Science Institute in Baltimore. “This could be the tip of the iceberg — these objects may be everywhere.”

We really know nothing about CX 330. More observations are required to determine more. It’s possible all young stars go through a similar outburst period as observed in the case of CX 330. The periods are just too brief in cosmological time for astronomers to observe with current technology. The real clue’s the isolation of this example as compared to previous models. 

How did CX 330 become so isolated? One idea often floated is the possibility it formed in a star-forming region, before being ejected to a more isolated region of space. This seems unlikely considering astronomers believe this young star’s only about a million years old. Even if this age’s wrong, this star’s still consuming its surrounding disk of dust and gas and must have formed near its current location. It just couldn’t have traveled the required distance from a star-forming region to its current location, without completely stripping away its surrounding disk of gas and dust. 

Astronomers are learning more about the formation of stars studying CX 330, that’s for sure. Using two competing ideas, called “hierarchical” and “competitive” models, scientists search for answers to unanswered questions concerning CX 330. At this point, they favor the chaotic and turbulent environment of the “hierarchical” model, as a better fit for the theoretical formation of a lone star.

What’s next?

It’s still possible material exists nearby CX 330, such as intermediate to low-mass stars, that astronomers haven’t observed, yet.  When last viewed in August 2015, this young star was still in an outburst phase. During future observations planned with new telescopes in different wavelengths, we could get a better picture of events surrounding this unusual celestial object. Stay tuned to this channel for more information.

For people wondering if planets could form around this young star? Some astronomers are hoping planets will form from the disk of CX 330, they’ll be able to examine closer for the chemical signature of the scars left by the outbursts observed. Unfortunately, at the rate this star’s consuming its surrounding disk of gas and dust, having enough left over for the formation of planets seems unlikely. 

“You said you like it hot, right!” If CX 330’s a really massive star, which seems likely. It’s short, violent lifespan would be a truly hot time for any planet and inhabitants. 

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How do Astronomers Precisely Determine Distances to Objects on the Other Side of the Milky Way Galaxy?

By studying light echoes, rings of x-rays observed around binary star system Circinus X-1

A light echo in X-rays detected by NASA’s Chandra X-ray Observatory has provided a rare opportunity to precisely measure the distance to an object on the other side of the Milky Way galaxy. The rings exceed the field-of-view of Chandra’s detectors, resulting in a partial image of X-ray data. Credits: NASA/CXC/U. Wisconsin/S. Heinz
The image above shows a light echo in x-rays detected by NASA’s Chandra X-ray Observatory which astronomers used to precisely measure the distance to a stellar object across the spiral disk of the Milky Way galaxy. The sizes of the light echoes detected in this image exceed the ability of the detectors, which has resulted in a partial construction of X-ray data. Credits: NASA/CXC/U. Wisconsin/S. Heinz

Space news (astrophysics: measuring distances of objects; light echoes) – 30,700 light-years from Earth in the plane of the Milky Way Galaxy, observing X-rays emitted by a neutron star in double star system Circinus X-1 reflecting off massive, surrounding clouds of gas and dust –

The youngest member of an important class of objects has been found using data from NASA's Chandra X-ray Observatory and the Australia Compact Telescope Array. A composite image shows the X-rays in blue and radio emission in purple, which have been overlaid on an optical field of view from the Digitized Sky Survey. This discovery, described in the press release, allows scientists to study a critical phase after a supernova and the birth of a neutron star.
The youngest member of an important class of objects has been found using data from NASA’s Chandra X-ray Observatory and the Australia Compact Telescope Array. A composite image shows the X-rays in blue and radio emission in purple, which have been overlaid on an optical field of view from the Digitized Sky Survey. This discovery allows scientists to study a critical phase after a supernova and the birth of a neutron star. Credits: NASA/Chandra

Determining the apparent distance of objects tens of thousands of light-years from Earth across the breadth of the Milky Way was a difficult problem to solve during the early days of the human journey to the beginning of space and time. During the years since these early days, astronomers have developed a few techniques and methods to help calculate distances to stellar objects on the other side of the galaxy. 

The most recently measured distance to an object on the other side of the Milky Way used the newest method developed. By detecting the rings from X-ray light echoes around the star Circinus X-1, a double star system containing a neutron star. Astronomers were able to determine the apparent distance to this system is around 30,700 light-years from Earth.

“It’s really hard to get accurate distance measurements in astronomy and we only have a handful of methods,” said Sebastian Heinz of the University of Wisconsin in Madison, who led the study. “But just as bats use sonar to triangulate their location, we can use the X-rays from Circinus X-1 to figure out exactly where it is.”

 Sebastian Heinz of the University of Wisconsin in Madison
Sebastian Heinz of the University of Wisconsin in Madison Credits: University of Wisconsin in Madison.

The rings are faint echoes from an outburst of x-rays emitted by Circinus X-1 near the end of 2013. The x-rays reflected off of separate clouds of gas and dust surrounding the star system, with some being sent toward Earth. The reflected x-rays arrived from different angles over a three month period, which created the observed X-ray rings. Using radio data scientists were able to determine the distance to each cloud of gas and dust, while detected X-ray echoes and simple geometry allowed for an accurate measurement of the distance to Circinus X-1 from Earth.

“We like to call this system the ‘Lord of the Rings,’ but this one has nothing to do with Sauron,” said co-author Michael Burton of the University of New South Wales in Sydney, Australia. “The beautiful match between the Chandra X-ray rings and the Mopra radio images of the different clouds is really a first in astronomy.”

Michael Burton of the University of New South Wales Credits: University of New South Wales
Michael Burton of the University of New South Wales Credits: University of New South Wales

In addition to this new distance measurement to Circinus X-1, astrophysicists determined this binary system’s naturally brighter in X-rays and other light than previously thought. This points to a star system that has repeatedly passed the threshold of brightness where the outward pressure of emitted radiation is balanced by the inward force of gravity. Astronomers have witnessed this equilibrium more often in binary systems containing a black hole, not a neutron star as in this case. The jet of high-energy particles emitted by this binary system’s also moving at 99.9 percent of the speed of light, which is a feature normally associated with a

The jet of high-energy particles emitted by this binary system’s also moving at 99.9 percent of the speed of light, which is a feature normally associated with a relativistic jet produced by a system containing a black hole. Scientists are currently studying this to see if they can determine why this system has such an unusual blend of characteristics.  

“Circinus X-1 acts in some ways like a neutron star and in some like a black hole,” said co-author Catherine Braiding, also of the University of New South Wales. “It’s extremely unusual to find an object that has such a blend of these properties.”

Astronomers think Circinus X-1 started emitting X-rays observers on Earth could have detected starting about 2,500 years ago. If this is true, this X-ray binary system’s the youngest detected, so far, during the human journey to the beginning of space and time.

This new X-ray data is being used to create a detailed three-dimensional map of the dust clouds between Circinus X-1 and Earth. 

What’s next?

Astrophysicists are preparing to measure distances to other stellar objects on the other side of the Milky Way using the latest distance measurement method. This new astronomy tool’s going to come in handy during the next leg of the human journey to the beginning of space and time.

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Chandra Detects X-ray Emissions of Comets PanSTARRS and ISON

Produced when heavy atoms in solar wind strike lighter atoms in comets’ atmosphere 

Astronomers used Chandra to observe Comet ISON and Comet PanSTARRS in 2013, when these comets were relatively close to the Earth. The graphic shows the comets in optical images taken by an astrophotographer, with insets showing the X-ray images from Chandra. The X-ray emission is produced when a wind of particles from the Sun – the solar wind – strikes the comet’s atmosphere. The Chandra data was used to estimate the composition of the solar wind, including the amount of carbon and nitrogen, finding values that agree with independent measurements. Image credit: X-ray: NASA/CXC/Univ. of CT/B.Snios et al, Optical: DSS, Damian Peach (damianpeach.com)
Astronomers used Chandra to observe Comet ISON and Comet PanSTARRS in 2013, when these comets were relatively close to the Earth. The graphic shows the comets in optical images taken by an astrophotographer, with insets showing the X-ray images from Chandra. The X-ray emission is produced when a wind of particles from the Sun – the solar wind – strikes the comet’s atmosphere. The Chandra data was used to estimate the composition of the solar wind, including the amount of carbon and nitrogen, finding values that agree with independent measurements.
Image credit: X-ray: NASA/CXC/Univ. of CT/B.Snios et al, Optical: DSS, Damian Peach (damianpeach.com)

Space news (planetary dynamics: Oort Cloud comets; PanSTARRS & ISON) – 90 & 130 million miles from Earth, respectively, observing x-ray emissions as solar wind particles strike comets’ atmosphere – 

Astronomers used Chandra to observe Comet ISON and Comet PanSTARRS in 2013, when these comets were relatively close to the Earth. The graphic shows the comets in optical images taken by an astrophotographer, with insets showing the X-ray images from Chandra. The X-ray emission is produced when a wind of particles from the Sun - the solar wind - strikes the comet's atmosphere. The Chandra data was used to estimate the composition of the solar wind, including the amount of carbon and nitrogen, finding values that agree with independent measurements.
Astronomers used Chandra to observe Comet ISON and Comet PanSTARRS in 2013, when these comets were relatively close to the Earth. The graphic shows the comets in optical images taken by an astrophotographer, with insets showing the X-ray images from Chandra. The X-ray emission is produced when a wind of particles from the Sun – the solar wind – strikes the comet’s atmosphere. The Chandra data was used to estimate the composition of the solar wind, including the amount of carbon and nitrogen, finding values that agree with independent measurements.

Thousands of years ago, ancient sky watchers observed terrible, fiery balls of fire that appeared suddenly in the sky. Hairy stars resembling fiery swords that appeared unpredictably, ancient astronomers and societies interpreted these terrifying, fear inducing travelers as harbingers of doom predicting impending disaster or even success in a future endeavor. Often connecting their appearance to famine, war, and plague, to the death of a beloved or fall of an empire or warlord, throughout history comets filled us with fear and even during modern times continue to entrance and fill us with awe. 

Comet ISON comes in from the bottom right and moves out toward the upper right, getting fainter and fainter, in this time-lapse image from the ESA/NASA Solar and Heliospheric Observatory. The image of the sun at the center is from NASA's Solar Dynamics Observatory. Image Credit: ESA/NASA/SOHO/SDO/GSFC
Comet ISON comes in from the bottom right and moves out toward the upper right, getting fainter and fainter, in this time-lapse image from the ESA/NASA Solar and Heliospheric Observatory. The image of the sun at the center is from NASA’s Solar Dynamics Observatory.
Image Credit: ESA/NASA/SOHO/SDO/GSFC

Recently, astronomers working with NASA’s Chandra X-ray Observatory detected x-ray emissions produced as particles in the solar wind struck the atmospheres’ of Comets ISON and PanSTARRS. Two long-period comets originating in the Oort Cloud far beyond the orbit of the planets, solar scientists use them as laboratories to study the composition of the stream of exotic particles flowing from the Sun called the solar wind. Astrophysicists determined x-ray emissions were produced as heavy particles in the solar wind struck lighter particles in the atmospheres’ of Comets ISON and PanSTARRS. X-ray emissions with varying shapes indicating differences in the solar wind and atmospheres’ of these comets at the time of the observations.  

This image from NASA's Solar Dynamics Observatory shows the sun, but no Comet ISON was seen. A white plus sign shows where the Comet should have appeared. It is likely that the comet did not survive the trip. Credits: NASA/SDO
This image from NASA’s Solar Dynamics Observatory shows the sun, but no Comet ISON was seen. A white plus sign shows where the Comet should have appeared. It is likely that the comet did not survive the trip.
Credits: NASA/SDO

Observations of Comet ISON detected a greenish hue attributed to gasses like cyanogen, which contains oxygen and nitrogen, streaming from its nucleus. Chandra data obtained shows this comet has a well-developed, parabolic shape indicative of a dense atmosphere. In comparison, observations of Comet PanSTARRS show a more diffuse x-ray spectrum, indicating it has less gas and more dust in its atmosphere. Observations that agree with independent measurements made by NASA’s Advanced Composition Explorer and other instruments. Planetary scientists plan to use the detailed computer simulations they developed during these studies to help analyze the data obtained by Chandra of Comets ISON and PanSTARRS to investigate interactions between the solar wind and other comets, planets, and even interstellar gas.  

Twelve NASA spacecraft assets had an opportunity to observe Comet ISON, including the Heliophysics solar observatories; Solar Dynamic Observatory, STEREO and SOHO. Credits: NASA
Twelve NASA spacecraft assets had an opportunity to observe Comet ISON, including the Heliophysics solar observatories; Solar Dynamic Observatory, STEREO and SOHO.
Credits: NASA

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Infrared Echoes Dance Around Cassiopeia A

Stretching over 300 light-years from the supernova remnant 

Credits: NASA/Spitzer
Credits: NASA/Spitzer

Space news (astrophysics: supernovae; Cassiopeia A remnant) – 11,000 light-years from Earth toward the northern constellation Cassiopeia the Queen – 

On the day in 1667 when a brilliant new star appeared in the sky in Cassiopeia the Queen, no written account is left to tell of the stellar event. The supernova remnant left over is called Cassiopeia A. It consists of a neutron star, with the first carbon atmosphere ever detected, and an expanding shell of material that was ejected from the star as it contracted under its own mass. The progenitor star of this supernova remnant was a supermassive star estimated to be between 15 to 20 times as massive as Sol. 

The composite image of the Cassiopeia A supernova remnant seen above was made using six processed images taken over a three year period by NASA’s Spitzer Space Telescope. It shows the largest light echoes ever detected at over 300 light-years in length, which were created as light from the explosion passed through clumps of dust surrounding the supernova remnant. This light illuminated and heated surrounding dust clumps, making them briefly glow in infrared, like a series of colored lights lighting up one after the other. This resulted in an optical illusion in which the dust appears to be traveling away from the remnant at the speed of light. This apparent motion is represented in this image by different dust colors, with dust features unchanged over time appearing gray, and changes in surrounding dust over time represented by blue or orange colors.  

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Cassiopeia A supernova remnant. Credits? NASA/Hubble/Spitzer

Supernova remnant Cassiopeia A is the brightest radio emission source in the night sky above the frequency of 1 Gigahertz. It’s expanding shell of material reaches speeds above 5,000 km/s and temperatures as high as 50 million degrees Fahrenheit. First detected by Martin Ryle and Francis Graham-Smith in 1948, since this time it has become one of the most studied supernova remnants during the human journey to the beginning of space and time. 

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For the first time, a multiwavelength three-dimensional reconstruction of a supernova remnant has been created in this stunning image of Cassiopeia A. Credits: NASA/Spitzer/Chandra/Kitt Peak

The startling false-color image above shows the many brilliant, stunning faces of the supernova remnant Cassiopeia A. Composed of images collected by three of the greatest space observatories in history, in three different wavebands of light. This view highlights the beauty hidden within one of the most violent events ever detected close by in the Milky Way. 

NASA’s Spitzer Space Telescope infrared images used to create this stunning picture show warm dust in the outer shell of the supernova remnant Cassiopeia A highlighted in red. Hubble Space Telescope images added reveal delicate filaments of hot gas around 10,000 degrees Kelvin (18,000 degrees Fahrenheit) in yellow, while x-ray data collected by NASA’s Chandra X-ray Observatory is shown in green and blue. Look a little closer and deeper at the image and one sees hints of older infrared echoes from after the supernova hundreds of years ago.  

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Wolf-Rayet Star “Nasty 1” Transitional Stage in Evolution of Massive Stars

A very rapidly evolving, supermassive star with a newly formed nebula only a few thousand years old

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Space news (supermassive stars: Wolf-Rayet stars; star NaSt1) – 3,000 light-years away on the edge of a pancake-shaped disk of gas moving at 22,000 mph – 

Astronomers using the Hubble Space Telescope have discovered new clues concerning a nearby supermassive, rapidly aging star they have nicknamed “Nasty 1”. Designated NaSt1 in astronomy catalogs, “Nasty 1” when first discovered decades ago was identified as a non-typical Wolf-Rayet star with an orbiting disk-like structure. A vast disk estimated to be almost 2 trillion miles wide astronomers now think formed due to a companion star snacking on its outer envelope. Putting NaSt1 in a class of Wolf-Rayet stars astronomers haven’t observed often during the human journey to the beginning of space and time. A star type possibly representing a transition stage in the evolution of supermassive stars. 

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“We were excited to see this disk-like structure because it may be evidence for a Wolf-Rayet star-forming from a binary interaction,” said study leader Jon Mauerhan of the University of California, Berkeley. “There are very few examples in the galaxy of this process in action because this phase is short-lived, perhaps lasting only a hundred thousand years, while the timescale over which a resulting disk is visible could be only ten thousand years or less.” 

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Study leader Jon Mauerhan of the University of California, Berkley. Credit: University of California, Berkley.

In the case of NaSt1, computer simulations show a supermassive star evolving really fast and swelling as it begins to run out of hydrogen. Its outer hydrogen envelope is loosely bound and is gravitationally stripped from the star- astronomers call this process stellar cannibalism – by a more compact, nearby companion star. In the process the more compact star gains mass, while the more massive star loses its hydrogen envelope, exposing its helium core and eventually becoming a Wolf-Rayet star. 

The mass-transfer model is the favored process for how Wolf-Rayet stars evolve at the moment and considering at least 70 percent of supermassive stars detected, so far, are members of binary star system, this seems logical. Astronomers used to think this type of star could also form when a massive sun ejects its hydrogen envelope. But the direct mass loss model by itself can’t account for the number of Wolf-Rayet stars observed relative to less-evolved supermassive suns in the Milky Way.  

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“We’re finding that it is hard to form all the Wolf-Rayet stars we observe by the traditional wind mechanism because the mass loss isn’t as strong as we used to think,” said Nathan Smith of the University of Arizona in Tucson, who is a co-author on the new NaSt1 paper. “Mass exchange in binary systems seems to be vital to account for Wolf-Rayet stars and the supernovae they make, and catching binary stars in this short-lived phase will help us understand this process.” 

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Co-author of study Nathan Smith of the University of Arizona in Tucson. Credit: The University of Arizona.

Astronomers computer models show that the mass-transfer process isn’t always perfectly efficient. Matter can only transfer from NaSt1 at a certain rate, left over material begins orbiting, creating a disk-like structure. 

“That’s what we think is happening in Nasty 1,” Mauerhan said. “We think there is a Wolf-Rayet star buried inside the nebula, and we think the nebula is being created by this mass-transfer process. So this type of sloppy stellar cannibalism actually makes Nasty 1 a rather fitting nickname.” 

Observing Nasty 1 (star NaSt1) through the clock of gas and dust surrounding this star system hasn’t been easy. The intervening disk-like structure even blocks the view of the Hubble Space Telescope. Scientists haven’t been able to measure the distance between the stars, their mass, or the volume of material transferring to the smaller companion star.  

Astronomers have been able to discover a few items concerning the disk-like structure surrounding Nasty 1. Measurements indicate it’s traveling at around 22,000 mph in the outer nebula, a slower speed than recorded in other stars of this type. Scientists think this indicates a much less energetic supernova than was recorded for other events, like Era Carinae. In this case and other similar stars, the gas in the outer nebula has been recorded in the hundreds of thousands of miles per hour. Nasty 1 could be different supernova animal altogether.  

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High atop the Cerro Manqui peak at the Las Campanas Observatory in Chile the twin the Walter Baade Telescope is the first of the twin 6.5-meter Magellan telescopes to be completed. Credit: Ico.cl

Nasty 1 could also lose its outer envelope of hydrogen intermittently. Previous studies in the infrared light provided clues indicating the existence of a dense pocket of hot gas and dust close to the central stars in the region. More recent observations using the Magellan Telescope located at the Las Campanas Observatory in Chile has also detected a bigger pocket of cooler gas and dust possibly indirectly blocking light from these stars. Astronomers think the existence of warm dust in the region implies it formed just recently, perhaps intermittently, as elementally enriched matter from the stellar winds of massive stars collides, mixes, flows away, and cools. Irregular stellar wind strength, the rate at which star NaSt1 loses its outer envelope, could also help explain the observed clumpy structure and gaps noted in the outer regions of the disk.  

Astrophysicists used NASA’s Chandra X-ray Observatory to measure the hypersonic winds screaming from each star. Readings showed a scorching hot plasma, indicating colliding stellar winds producing high-energy shockwaves that glow in X-rays. This is consistent with previous data collected on other evolving Wolf-Rayet star systems. We’ll get a better view once the outer hydrogen of Nasty 1’s (star NaSt1) depleted, and the mass-transfer process completes. Eventually, the gas and dust in the lumpy, disk-like structure will dissipate, giving us a clearer view of this mysterious binary star system.   

 

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NASA’s Chandra X-ray Observatory has shown the cosmos is full of objects and events far beyond anything we imagined when we first started the human journey to the beginning of space and time. Credit: NASA/Chandra

Nasty 1’s still evolving!

“What evolutionary path the star will take is uncertain, but it will definitely not be boring,” said Mauerhan. “Nasty 1 could evolve into another Eta Carinae-type system. To make that transformation, the mass-gaining companion star could experience a giant eruption because of some instability related to the acquiring of matter from the newly formed Wolf-Rayet. Or, the Wolf-Rayet could explode as a supernova. A stellar merger is another potential outcome, depending on the orbital evolution of the system. The future could be full of all kinds of exotic possibilities depending on whether it blows up or how long the mass transfer occurs, and how long it lives after the mass transfer ceases.” 

Astronomers continue to study Nasty 1 and its peculiar, unusual disk-like structure looking for clues to explain the mysteries surrounding its origin. 

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NASA’s Chandra Detects X-rays Emitted by Distant Supermassive Black Hole

Discovery shows distant supermassive black holes with relativistic jets could be more common than astronomers first thought 

This main panel graphic shows Chandra’s X-ray data that have been combined with an optical image from the Digitized Sky Survey. (Note that the two sources near the center of the image do not represent a double source, but rather a coincidental alignment of the distant jet and a foreground galaxy.) The inset shows more detail of the X-ray emission from the jet detected by Chandra. The length of the jet in 0727+409 is at least 300,000 light years. Many long jets emitted by supermassive black holes have been detected in the nearby Universe, but exactly how these jets give off X-rays has remained a matter of debate. In B3 0727+409, it appears that the CMB is being boosted to X-ray wavelengths. Credit: NASA/Chandra
This main panel graphic shows Chandra’s X-ray data that have been combined with an optical image from the Digitized Sky Survey. (Note that the two sources near the center of the image do not represent a double source, but rather a coincidental alignment of the distant jet and a foreground galaxy.)
The inset shows more detail of the X-ray emission from the jet detected by Chandra. 
Credit: NASA/Chandra

Space news (March 06, 2016) – over 11 billion light-years from Earth – 

Astronomers working with NASA’s Chandra X-ray Observatory recently discovered a distant, powerful jet emanating from a quasar called B3 0727+409 while observing another stellar object. The system discovered was interesting because scientists had previously found very few early supermassive black holes with powerful jets giving off X-rays. This discovery has astronomers looking for data to confirm the belief supermassive black holes with powerful jets were more common during the first few billion years after the Big Bang than first thought. 

Astronomers were lucky to detect this quasar since no radio signal has been detected from this object. Normally, they would detect similar quasars using radio observations but will use this opportunity to study how these jets emit X-rays. This question has been a matter of debate among astrophysicists, but in this case, they have a few clues to follow.  

We essentially stumbled onto this remarkable jet because it happened to be in Chandra’s field of view while we were observing something else,” explains co-author Lukasz Stawarz of Jagiellonian University in Poland. 

The light from the jet emanating from quasar B3 0727+409 was emitted when the universe was only 2.7 billion years old, or just over twenty percent of its present age. At this time the intensity of the microwave background microwave radiation (CMB) remaining after the Big Bang was much greater than today. In this case, it looks like the CMB is somehow being boosted to X-ray wavelengths and astronomers think this could be a lead. 

Because we’re seeing this jet when the Universe was less than three billion years old, the jet is about 150 times brighter in X-rays than it would be in the nearby Universe,” said Aurora Simionescu at JAXA’s Institute of Space and Astronautical Studies (ISAS) who led the study.  

Computer simulations show that as electrons in the jet fly from the supermassive black hole at nearly the speed of light, they collide with microwave photons in the CMB and boost their energy into the X-ray band. This is the X-ray signal Chandra detected, but this means the electrons in the jet must continue to move at this speed for its entire length, which is over 300,000 light-years. A finding that has scientists scratching their heads. 

Astronomers have detected many long jets emitted by nearby supermassive black holes, but very few from early quasars with jets emitting X-rays. Astronomers could have missed many similar systems since they weren’t trying to detect them. Now, they’ll follow the breadcrumbs to get a better picture of the early universe and try to understand the evolution of supermassive black holes during the past 13.77 billion years a little better.    

Astronomers look for similar events to study in detail

Scientists have so far identified very few jets distant enough that their X-ray brightness is amplified by the CMB as clearly as in the B3 0727+409 system.” But, Stawarz adds, “if bright X-ray jets can exist with very faint or undetected radio counterparts, it means that there could be much more of them out there because we haven’t been systematically looking for them.” 

Supermassive black hole activity, including the launching of jets, may be different in the early Universe than what we see later on,” said co-author Teddy Cheung of the Naval Research Laboratory in Washington DC. “By finding and studying more of these distant jets, we can start to grasp how the properties of supermassive black holes might change over billions of years.” 

You can take a video tour of B3 0727+409 aboard the Chandra X-ray Observatory here.

We’ll update you as astronomers learn more about relativistic jets and similar systems. 

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Learn more about NASA’s journey to the stars and future plans here.

You can take the journey of the Chandra X-ray Observatory

Learn more about what astronomers have discovered about supermassive black holes here

Read and discover more about quasar B3 0727+409

Supermassive Black Hole in Small Galaxy NGC 5195 Burps After a Meal

Producing a super powerful blast observed by NASA’s Chandra X-ray Observatory

ngc5195
The main panel of this graphic shows M51 in visible light data from the Hubble Space Telescope (red, green, and blue). The box at the top of the image outlines the field of view by Chandra in the latest study, which focuses on the smaller component of M51, NGC 5195. The inset to the right shows the details of the Chandra data (blue) of this region. Researchers found a pair of arcs in X-ray emission close to the center of the galaxy, which they interpret as two outbursts from the galaxy’s supermassive black hole (see annotated image for additional information). Credits: NASA/Chandra

Space news (February 22, 2016) – 26 million light-years from Earth, deep within the Messier 51 galaxy system – 

Astronomers using NASA’s Chandra X-ray Observatory recently caught the supermassive black hole in galaxy NGC 5195 burping after a meal composed of gas and maybe even stars. This giant black hole is one of the closest to Earth that’s currently erupting violent blasts of X-rays. Studying these violent outbursts presents an opportunity to learn more about the processes creating some of the most energetic events observed in the cosmos. 

“For an analogy, astronomers often refer to black holes as ‘eating’ stars and gas.  Apparently, black holes can also burp after their meal,” said Eric Schlegel of The University of Texas at San Antonio, who led the study. “Our observation is important because this behavior would likely happen very often in the early universe, altering the evolution of galaxies. It is common for big black holes to expel gas outward, but rare to have such a close, resolved view of these events.” 

A smaller companion galaxy, NGC 5195 is currently merging with a larger spiral galaxy NGC 5194 (The Whirlpool). Astronomers believe this ongoing merger was the trigger for the two arcs of X-ray emission they originally detected near its center. The energy released as the supermassive black hole expelled material outward into the cosmos would be sufficient to produce the X-ray arcs detected. Material that was part of the original gas that was funneled toward the supermassive black hole as the two galaxies interacted over millions of years would suffice. 

“We think these arcs represent fossils from two enormous blasts when the black hole expelled material outward into the galaxy,” said co-author Christine Jones of the Harvard-Smithsonian Center for Astrophysics (CfA) in Cambridge, Mass. “This activity is likely to have had a big effect on the galactic landscape.” 

Astronomers followed up the original observations of these arcs by Chandra using the 0.9-meter telescope at the Kitt Peak National Observatory. They detected a slender region of emission of relatively cool hydrogen gas in an optical image suggesting X-ray emitting gas swept up hydrogen gas from the center of the galaxy. Scientists call this phenomenon by which a supermassive black hole changes its host galaxy “feedback”. 

In the case of the X-ray glowing arcs astronomers observed coming from the region of the supermassive black hole in the center of companion galaxy NGC 5195. Scientists believe the outer arc plowed up enough gas and material to start the formation of new stars over a period of three to six million years. This points to the “feedback” phenomenon being a process of creation in the universe, not just massive destruction.  

“We think that feedback keeps galaxies from becoming too large,” said co-author Marie Machacek of CfA. “But at the same time, it can be responsible for how some stars form. This shows that black holes can create, not just destroy.” 

Astrophysicists also want to study the blasts emanating from near the supermassive black hole because of their location in galaxy NGC 5195. In previously detected active supermassive black holes in other galaxies, rapid outflows haven’t been detected in regions this far out. It could be possible we’re viewing an intermediate stage in the feedback process operating between the black hole and interstellar gas. 

Study continues

Scientists will continue to study the powerful blasts coming from the supermassive black hole at the center of galaxy NGC 5195. This will allow them to gain knowledge on how these massive blasts change the environment of their home galaxy. It will also allow them to study how these powerful blasts would alter the evolution of a galaxy.  

Take a video tour of dwarf galaxy NGC 5195 aboard the Chandra X-ray Observatory here.

Read about the recent observation of gravitational waves by astronomers using the Chandra X-ray Observatory. 

Learn more about the youngest, nearby black hole candidate.

Learn more about mysterious ripples astronomers detected moving across the planet-forming region of a star.

We’ll update you if they detect any after burps from the supermassive black hole. 

You can learn more about NASA and its future plans here

Discover the Chandra X-ray Observatory here

Learn more about galaxy NGC 5195

Learn more about active supermassive black holes