Latest news with #FarhadYusef-Zadeh
Yahoo
09-05-2025
- Science
- Yahoo
This Galactic 'Bone' Was Smashed by a Pulsar Clocking Up to 2 Million MPH
The culprit in a cosmic hit-and-run that resulted in a broken 'bone' has been found out. Of course, it's not actually a bone at all, but a mind-blowingly huge filament in the center of the Milky Way galaxy, known as the Snake, extending for a length of 230 light-years. One of the interesting things about this filament is that it's relatively smooth – except for two prominent kinks, or "breaks". The origin of the fractures in the Snake (G359.13) was something of a mystery; observations using the Chandra X-ray Observatory and the MeerKAT radio telescope revealed the culprit of one of them. Zooming in on one of the fractures identified a prominent point-like source of X-rays and radio waves. A team of astronomers, led by Farhad Yusef-Zadeh of Northwestern University in the US, thinks it could only be a radio pulsar that punched through the filament at an absolutely breakneck velocity of between 500 and 1,000 kilometers (310 to 620 miles) per second. This, believe it or not, is not unheard-of for pulsars. That's because pulsars are dead stars – the collapsed cores of massive stars that have reached the end of their lifespan and sneezed off their outer material in a violent supernova. The core of the star, no longer supported by the outward pressure of fusion, collapses under gravity to form a neutron star that, when it pulses with light, we call a pulsar. If this supernova is lopsided, the neutron star can be booted unceremoniously across the galaxy at high speeds, something astronomers call a natal kick. The famous cannonball pulsar is thought to have received a natal kick; and other high-speed stars show just how powerful this blow can be. We don't know the origin of the pulsar smashing through the Snake, but it seems to be doing so with quite some force. The filament is made of magnetic fields, along which spiraling particles are accelerated, causing the filament to glow. Around the fracture, the radio emission glows more strongly, suggesting that the force of the blow warped the magnetic field, distorting the radio signal. Meanwhile, an enhancement in X-rays near the pulsar is consistent with accelerated electrons and positrons. The cause of the second, smaller fracture is yet to be determined. There is also more to discover about the pulsar. If it's traveling fast enough, it may some day leave the galaxy. But since it's in the galactic center, some 26,000 light-years from us, it has a long road ahead of it. A paper describing these findings was published in May 2024 in the Monthly Notices of the Royal Astronomical Society. Giant Impacts Could Trigger Seismic Vibrations Lasting Millions of Years Scientists Have a Radical Plan to Grab a Sample of Venus's Toxic Atmosphere JWST Helps Decipher Mysterious Nature of Hot Alien World
Yahoo
19-02-2025
- Science
- Yahoo
Astronomers spot flares of light near the black hole at the center of our galaxy
Sign up for CNN's Wonder Theory science newsletter. Explore the universe with news on fascinating discoveries, scientific advancements and more. Astronomers using the James Webb Space Telescope have spied dynamic flares of light near the supermassive black hole at the center of the Milky Way galaxy. The constant, rapid-fire display includes seconds-long short flashes and longer, blindingly bright flares of light on a daily basis. The Webb observations mark the longest, most detailed look researchers have been able to make around the Milky Way's central black hole, called Sagittarius A*, building on past evidence of its highly energetic activity. While black holes are invisible, the flares unleashed by the swirling disk of hot gas and dust, or accretion disk, that orbits Sagittarius A* resemble a pyrotechnic extravaganza. A study describing the findings was published Tuesday in The Astrophysical Journal Letters. Astronomers believe the flares are coming from the inner edge of the accretion disk just beyond the black hole's event horizon, or the area around a black hole where the pull of gravity is so strong that not even light can escape, according to NASA. 'In our data, we saw constantly changing, bubbling brightness,' said lead study author Farhad Yusef-Zadeh, a professor of physics and astronomy at Northwestern University's Weinberg College of Arts and Sciences, in a statement. 'And then boom! A big burst of brightness suddenly popped up. Then, it calmed down again. We couldn't find a pattern in this activity. It appears to be random. The activity profile of this black hole was new and exciting every time that we looked at it.' The observations could shed light on how black holes behave and the ways they feed on their surroundings. The strong, gravitational influence of black holes pulls in gas and dust from any celestial object that wanders too close. The gas and dust swirl together at high speeds, forming the accretion disk that feeds the black hole. The rapid movement of the material causes it to heat up, releasing energy in the form of radiation as well as jets of material that don't make it into the black hole. The radiation and jets can change the way gas is distributed throughout galaxies and feed the formation of stars, which is why supermassive black holes are regarded as giant engines at the centers of galaxies. Yusef-Zadeh and his colleagues observed Sagittarius A*, also called Sgr A*, for 48 hours over the course of one year in eight to 10-hour increments, using Webb's Near-Infrared Camera to track the black hole's activity. The team spied five to six big flares a day as well as smaller flashes of light in between. 'Flares are expected to happen in essentially all supermassive black holes, but our black hole is unique,' Yusef-Zadeh said. 'It is always bubbling with activity and never seems to reach a steady state. We observed the black hole multiple times throughout 2023 and 2024, and we noticed changes in every observation. We saw something different each time, which is really remarkable.' The variability of the black hole's activity is likely due to the random nature of the material flowing into the accretion disk, Yusef-Zadeh said. The team believes the short bursts of light are created by minor, turbulent fluctuations within the accretion disk that could squeeze hot, energetic gas called plasma and cause a flash of radiation. 'It's similar to how the Sun's magnetic field gathers together, compresses, and then erupts a solar flare,' Yusef-Zadeh said in a statement. 'Of course, the processes are more dramatic because the environment around a black hole is much more energetic and much more extreme.' Meanwhile, the longer, bigger flares may occur due to magnetic reconnection events, or when two different magnetic fields collide near the black hole and release energetic particles moving near the speed of light. 'A magnetic reconnection event is like a spark of static electricity, which, in a sense, also is an 'electric reconnection,'' Yusef-Zadeh said. Webb's capabilities enabled the team to observe the black hole's flaring across two different wavelengths of light simultaneously. '(It was like) seeing the world in color versus in black and white, and (we) found rainbows,' Yusef-Zadeh said. 'This tells you about the nature of flaring activity and the physical characteristics of the radiation mechanism, the magnetic field and the density of flares more directly.' The observations provide a deeper look at how the black hole's activity varies in brightness over time, said Tuan Do, associate professor in the physics and astronomy department and deputy director of the Galactic Center Group at UCLA. Do was not involved in this study but has led research on Sagittarius A* in the past, including when the black hole showcased unusual activity in 2019. 'Sgr A* got about half as bright in the new data as was seen in 2019, so I think that 2019 is still unusually active for the black hole,' Do said. 'The black hole and its environment (are) always changing though so we are never sure what we'll find! This is what makes observations of the galactic center so exciting, even though we've stared at this spot in the sky for decades now.' When the authors of the latest study observed the two different wavelengths of light from the black hole simultaneously, they realized the shorter wavelength changed in brightness just before the longer wavelength. The observation suggested that as the particles spiral around magnetic field lines, they lose energy more quickly. The changes in brightness have been noted in previous research and recent complementary data from the Mid-Infrared Instrument on the Webb telescope and other observatories. 'I think the next big step would be to try to connect these different data sources together to form a fuller picture of the physics of the environment around the supermassive black hole,' Do said. The new study also confirms the black hole has 'non-stop variability,' as previously observed, said Mark Morris, distinguished research professor in the department of physics and astronomy at UCLA. Morris was not involved in the new study. 'X-ray astronomers see reasonably strong evidence that in the last few hundred years, there has been at least one, maybe two instances of enormous flares taking place,' Morris said via email, 'with intensities (10,000 to 100,000) times larger than anything we've seen in the last quarter century that we have been closely examining Sgr A*.' What might have caused these flares? Astronomers still don't know, but it's possible the black hole gobbled up a planet a few hundred years ago, Morris said. When the sun releases solar storms, scientists worry because such activity can potentially affect GPS, communications and the power grid on Earth. But at 25,000 light-years away, the highly energetic and variable activity of the Milky Way's central black hole isn't a concern, Morris said. However, the Webb telescope observations allow researchers to understand what kind of 'storms' are created when matter is compressed and heated as it is drawn toward the black hole. 'Beyond pure interest in the most dazzling fireworks that the universe can produce, those fireworks can have a profound effect on the evolution of the galaxies that they are in,' Morris said. 'They can provoke or impede star formation on large scales, they can remove gas and clear out galaxies, leaving them unable to form stars.' The study authors don't believe the black hole was experiencing an unusual spike in activity, but they want to observe Sagittarius A* for an uninterrupted 24 hours to be sure. 'We also can see if these flares show periodicity (or repeat themselves) or if they are truly random,' Yusef-Zadeh said. Astronomers still don't know how fast Sagittarius A* is spinning as it gobbles up matter, but longer observations could provide the data necessary to find the answer. Ultimately, more data from Webb observations of Sagittarius A* could help astronomers simulate how accretion disks behave around black holes, as well as comparing the behaviors of less energetically active, black holes with more active ones.
CNN
19-02-2025
- Science
- CNN
Webb telescope spies the Milky Way's black hole constantly ‘bubbling' with light
Astronomers using the James Webb Space Telescope have spied dynamic flares of light near the supermassive black hole at the center of the Milky Way galaxy. The constant, rapid-fire display includes seconds-long short flashes and longer, blindingly bright flares of light on a daily basis. The Webb observations mark the longest, most detailed look researchers have been able to make around the Milky Way's central black hole, called Sagittarius A*, building on past evidence of its highly energetic activity. While black holes are invisible, the flares unleashed by the swirling disk of hot gas and dust, or accretion disk, that orbits Sagittarius A* resemble a pyrotechnic extravaganza. A study describing the findings was published Tuesday in The Astrophysical Journal Letters. Astronomers believe the flares are coming from the inner edge of the accretion disk just beyond the black hole's event horizon, or the area around a black hole where the pull of gravity is so strong that not even light can escape, according to NASA. 'In our data, we saw constantly changing, bubbling brightness,' said lead study author Farhad Yusef-Zadeh, a professor of physics and astronomy at Northwestern University's Weinberg College of Arts and Sciences, in a statement. 'And then boom! A big burst of brightness suddenly popped up. Then, it calmed down again. We couldn't find a pattern in this activity. It appears to be random. The activity profile of this black hole was new and exciting every time that we looked at it.' The observations could shed light on how black holes behave and the ways they feed on their surroundings. Watching celestial fireworks The strong, gravitational influence of black holes pulls in gas and dust from any celestial object that wanders too close. The gas and dust swirl together at high speeds, forming the accretion disk that feeds the black hole. The rapid movement of the material causes it to heat up, releasing energy in the form of radiation as well as jets of material that don't make it into the black hole. The radiation and jets can change the way gas is distributed throughout galaxies and feed the formation of stars, which is why supermassive black holes are regarded as giant engines at the centers of galaxies. Yusef-Zadeh and his colleagues observed Sagittarius A*, also called Sgr A*, for 48 hours over the course of one year in eight to 10-hour increments, using Webb's Near-Infrared Camera to track the black hole's activity. The team spied five to six big flares a day as well as smaller flashes of light in between. 'Flares are expected to happen in essentially all supermassive black holes, but our black hole is unique,' Yusef-Zadeh said. 'It is always bubbling with activity and never seems to reach a steady state. We observed the black hole multiple times throughout 2023 and 2024, and we noticed changes in every observation. We saw something different each time, which is really remarkable.' The variability of the black hole's activity is likely due to the random nature of the material flowing into the accretion disk, Yusef-Zadeh said. The team believes the short bursts of light are created by minor, turbulent fluctuations within the accretion disk that could squeeze hot, energetic gas called plasma and cause a flash of radiation. 'It's similar to how the Sun's magnetic field gathers together, compresses, and then erupts a solar flare,' Yusef-Zadeh said in a statement. 'Of course, the processes are more dramatic because the environment around a black hole is much more energetic and much more extreme.' Meanwhile, the longer, bigger flares may occur due to magnetic reconnection events, or when two different magnetic fields collide near the black hole and release energetic particles moving near the speed of light. 'A magnetic reconnection event is like a spark of static electricity, which, in a sense, also is an 'electric reconnection,'' Yusef-Zadeh said. A 'rainbow' of activity Webb's capabilities enabled the team to observe the black hole's flaring across two different wavelengths of light simultaneously. '(It was like) seeing the world in color versus in black and white, and (we) found rainbows,' Yusef-Zadeh said. 'This tells you about the nature of flaring activity and the physical characteristics of the radiation mechanism, the magnetic field and the density of flares more directly.' The observations provide a deeper look at how the black hole's activity varies in brightness over time, said Tuan Do, associate professor in the physics and astronomy department and deputy director of the Galactic Center Group at UCLA. Do was not involved in this study but has led research on Sagittarius A* in the past, including when the black hole showcased unusual activity in 2019. 'Sgr A* got about half as bright in the new data as was seen in 2019, so I think that 2019 is still unusually active for the black hole,' Do said. 'The black hole and its environment (are) always changing though so we are never sure what we'll find! This is what makes observations of the galactic center so exciting, even though we've stared at this spot in the sky for decades now.' When the authors of the latest study observed the two different wavelengths of light from the black hole simultaneously, they realized the shorter wavelength changed in brightness just before the longer wavelength. The observation suggested that as the particles spiral around magnetic field lines, they lose energy more quickly. The changes in brightness have been noted in previous research and recent complementary data from the Mid-Infrared Instrument on the Webb telescope and other observatories. 'I think the next big step would be to try to connect these different data sources together to form a fuller picture of the physics of the environment around the supermassive black hole,' Do said. The new study also confirms the black hole has 'non-stop variability,' as previously observed, said Mark Morris, distinguished research professor in the department of physics and astronomy at UCLA. Morris was not involved in the new study. 'X-ray astronomers see reasonably strong evidence that in the last few hundred years, there has been at least one, maybe two instances of enormous flares taking place,' Morris said via email, 'with intensities (10,000 to 100,000) times larger than anything we've seen in the last quarter century that we have been closely examining Sgr A*.' What might have caused these flares? Astronomers still don't know, but it's possible the black hole gobbled up a planet a few hundred years ago, Morris said. When the sun releases solar storms, scientists worry because such activity can potentially affect GPS, communications and the power grid on Earth. But at 25,000 light-years away, the highly energetic and variable activity of the Milky Way's central black hole isn't a concern, Morris said. However, the Webb telescope observations allow researchers to understand what kind of 'storms' are created when matter is compressed and heated as it is drawn toward the black hole. 'Beyond pure interest in the most dazzling fireworks that the universe can produce, those fireworks can have a profound effect on the evolution of the galaxies that they are in,' Morris said. 'They can provoke or impede star formation on large scales, they can remove gas and clear out galaxies, leaving them unable to form stars.' A longer look The study authors don't believe the black hole was experiencing an unusual spike in activity, but they want to observe Sagittarius A* for an uninterrupted 24 hours to be sure. 'We also can see if these flares show periodicity (or repeat themselves) or if they are truly random,' Yusef-Zadeh said. Astronomers still don't know how fast Sagittarius A* is spinning as it gobbles up matter, but longer observations could provide the data necessary to find the answer. Ultimately, more data from Webb observations of Sagittarius A* could help astronomers simulate how accretion disks behave around black holes, as well as comparing the behaviors of less energetically active, black holes with more active ones.
CNN
19-02-2025
- Science
- CNN
Webb telescope spies the Milky Way's black hole constantly ‘bubbling' with light
Astronomers using the James Webb Space Telescope have spied dynamic flares of light near the supermassive black hole at the center of the Milky Way galaxy. The constant, rapid-fire display includes seconds-long short flashes and longer, blindingly bright flares of light on a daily basis. The Webb observations mark the longest, most detailed look researchers have been able to make around the Milky Way's central black hole, called Sagittarius A*, building on past evidence of its highly energetic activity. While black holes are invisible, the flares unleashed by the swirling disk of hot gas and dust, or accretion disk, that orbits Sagittarius A* resemble a pyrotechnic extravaganza. A study describing the findings was published Tuesday in The Astrophysical Journal Letters. Astronomers believe the flares are coming from the inner edge of the accretion disk just beyond the black hole's event horizon, or the area around a black hole where the pull of gravity is so strong that not even light can escape, according to NASA. 'In our data, we saw constantly changing, bubbling brightness,' said lead study author Farhad Yusef-Zadeh, a professor of physics and astronomy at Northwestern University's Weinberg College of Arts and Sciences, in a statement. 'And then boom! A big burst of brightness suddenly popped up. Then, it calmed down again. We couldn't find a pattern in this activity. It appears to be random. The activity profile of this black hole was new and exciting every time that we looked at it.' The observations could shed light on how black holes behave and the ways they feed on their surroundings. Watching celestial fireworks The strong, gravitational influence of black holes pulls in gas and dust from any celestial object that wanders too close. The gas and dust swirl together at high speeds, forming the accretion disk that feeds the black hole. The rapid movement of the material causes it to heat up, releasing energy in the form of radiation as well as jets of material that don't make it into the black hole. The radiation and jets can change the way gas is distributed throughout galaxies and feed the formation of stars, which is why supermassive black holes are regarded as giant engines at the centers of galaxies. Yusef-Zadeh and his colleagues observed Sagittarius A*, also called Sgr A*, for 48 hours over the course of one year in eight to 10-hour increments, using Webb's Near-Infrared Camera to track the black hole's activity. The team spied five to six big flares a day as well as smaller flashes of light in between. 'Flares are expected to happen in essentially all supermassive black holes, but our black hole is unique,' Yusef-Zadeh said. 'It is always bubbling with activity and never seems to reach a steady state. We observed the black hole multiple times throughout 2023 and 2024, and we noticed changes in every observation. We saw something different each time, which is really remarkable.' The variability of the black hole's activity is likely due to the random nature of the material flowing into the accretion disk, Yusef-Zadeh said. The team believes the short bursts of light are created by minor, turbulent fluctuations within the accretion disk that could squeeze hot, energetic gas called plasma and cause a flash of radiation. 'It's similar to how the Sun's magnetic field gathers together, compresses, and then erupts a solar flare,' Yusef-Zadeh said in a statement. 'Of course, the processes are more dramatic because the environment around a black hole is much more energetic and much more extreme.' Meanwhile, the longer, bigger flares may occur due to magnetic reconnection events, or when two different magnetic fields collide near the black hole and release energetic particles moving near the speed of light. 'A magnetic reconnection event is like a spark of static electricity, which, in a sense, also is an 'electric reconnection,'' Yusef-Zadeh said. A 'rainbow' of activity Webb's capabilities enabled the team to observe the black hole's flaring across two different wavelengths of light simultaneously. '(It was like) seeing the world in color versus in black and white, and (we) found rainbows,' Yusef-Zadeh said. 'This tells you about the nature of flaring activity and the physical characteristics of the radiation mechanism, the magnetic field and the density of flares more directly.' The observations provide a deeper look at how the black hole's activity varies in brightness over time, said Tuan Do, associate professor in the physics and astronomy department and deputy director of the Galactic Center Group at UCLA. Do was not involved in this study but has led research on Sagittarius A* in the past, including when the black hole showcased unusual activity in 2019. 'Sgr A* got about half as bright in the new data as was seen in 2019, so I think that 2019 is still unusually active for the black hole,' Do said. 'The black hole and its environment (are) always changing though so we are never sure what we'll find! This is what makes observations of the galactic center so exciting, even though we've stared at this spot in the sky for decades now.' When the authors of the latest study observed the two different wavelengths of light from the black hole simultaneously, they realized the shorter wavelength changed in brightness just before the longer wavelength. The observation suggested that as the particles spiral around magnetic field lines, they lose energy more quickly. The changes in brightness have been noted in previous research and recent complementary data from the Mid-Infrared Instrument on the Webb telescope and other observatories. 'I think the next big step would be to try to connect these different data sources together to form a fuller picture of the physics of the environment around the supermassive black hole,' Do said. The new study also confirms the black hole has 'non-stop variability,' as previously observed, said Mark Morris, distinguished research professor in the department of physics and astronomy at UCLA. Morris was not involved in the new study. 'X-ray astronomers see reasonably strong evidence that in the last few hundred years, there has been at least one, maybe two instances of enormous flares taking place,' Morris said via email, 'with intensities (10,000 to 100,000) times larger than anything we've seen in the last quarter century that we have been closely examining Sgr A*.' What might have caused these flares? Astronomers still don't know, but it's possible the black hole gobbled up a planet a few hundred years ago, Morris said. When the sun releases solar storms, scientists worry because such activity can potentially affect GPS, communications and the power grid on Earth. But at 25,000 light-years away, the highly energetic and variable activity of the Milky Way's central black hole isn't a concern, Morris said. However, the Webb telescope observations allow researchers to understand what kind of 'storms' are created when matter is compressed and heated as it is drawn toward the black hole. 'Beyond pure interest in the most dazzling fireworks that the universe can produce, those fireworks can have a profound effect on the evolution of the galaxies that they are in,' Morris said. 'They can provoke or impede star formation on large scales, they can remove gas and clear out galaxies, leaving them unable to form stars.' A longer look The study authors don't believe the black hole was experiencing an unusual spike in activity, but they want to observe Sagittarius A* for an uninterrupted 24 hours to be sure. 'We also can see if these flares show periodicity (or repeat themselves) or if they are truly random,' Yusef-Zadeh said. Astronomers still don't know how fast Sagittarius A* is spinning as it gobbles up matter, but longer observations could provide the data necessary to find the answer. Ultimately, more data from Webb observations of Sagittarius A* could help astronomers simulate how accretion disks behave around black holes, as well as comparing the behaviors of less energetically active, black holes with more active ones.
Yahoo
19-02-2025
- Science
- Yahoo
Webb telescope spies the Milky Way's black hole constantly ‘bubbling' with light
Sign up for CNN's Wonder Theory science newsletter. Explore the universe with news on fascinating discoveries, scientific advancements and more. Astronomers using the James Webb Space Telescope have spied dynamic flares of light near the supermassive black hole at the center of the Milky Way galaxy. The constant, rapid-fire display includes seconds-long short flashes and longer, blindingly bright flares of light on a daily basis. The Webb observations mark the longest, most detailed look researchers have been able to make around the Milky Way's central black hole, called Sagittarius A*, building on past evidence of its highly energetic activity. While black holes are invisible, the flares unleashed by the swirling disk of hot gas and dust, or accretion disk, that orbits Sagittarius A* resemble a pyrotechnic extravaganza. A study describing the findings was published Tuesday in The Astrophysical Journal Letters. Astronomers believe the flares are coming from the inner edge of the accretion disk just beyond the black hole's event horizon, or the area around a black hole where the pull of gravity is so strong that not even light can escape, according to NASA. 'In our data, we saw constantly changing, bubbling brightness,' said lead study author Farhad Yusef-Zadeh, a professor of physics and astronomy at Northwestern University's Weinberg College of Arts and Sciences, in a statement. 'And then boom! A big burst of brightness suddenly popped up. Then, it calmed down again. We couldn't find a pattern in this activity. It appears to be random. The activity profile of this black hole was new and exciting every time that we looked at it.' The observations could shed light on how black holes behave and the ways they feed on their surroundings. The strong, gravitational influence of black holes pulls in gas and dust from any celestial object that wanders too close. The gas and dust swirl together at high speeds, forming the accretion disk that feeds the black hole. The rapid movement of the material causes it to heat up, releasing energy in the form of radiation as well as jets of material that don't make it into the black hole. The radiation and jets can change the way gas is distributed throughout galaxies and feed the formation of stars, which is why supermassive black holes are regarded as giant engines at the centers of galaxies. Yusef-Zadeh and his colleagues observed Sagittarius A*, also called Sgr A*, for 48 hours over the course of one year in eight to 10-hour increments, using Webb's Near-Infrared Camera to track the black hole's activity. The team spied five to six big flares a day as well as smaller flashes of light in between. 'Flares are expected to happen in essentially all supermassive black holes, but our black hole is unique,' Yusef-Zadeh said. 'It is always bubbling with activity and never seems to reach a steady state. We observed the black hole multiple times throughout 2023 and 2024, and we noticed changes in every observation. We saw something different each time, which is really remarkable.' The variability of the black hole's activity is likely due to the random nature of the material flowing into the accretion disk, Yusef-Zadeh said. The team believes the short bursts of light are created by minor, turbulent fluctuations within the accretion disk that could squeeze hot, energetic gas called plasma and cause a flash of radiation. 'It's similar to how the Sun's magnetic field gathers together, compresses, and then erupts a solar flare,' Yusef-Zadeh said in a statement. 'Of course, the processes are more dramatic because the environment around a black hole is much more energetic and much more extreme.' Meanwhile, the longer, bigger flares may occur due to magnetic reconnection events, or when two different magnetic fields collide near the black hole and release energetic particles moving near the speed of light. 'A magnetic reconnection event is like a spark of static electricity, which, in a sense, also is an 'electric reconnection,'' Yusef-Zadeh said. Webb's capabilities enabled the team to observe the black hole's flaring across two different wavelengths of light simultaneously. '(It was like) seeing the world in color versus in black and white, and (we) found rainbows,' Yusef-Zadeh said. 'This tells you about the nature of flaring activity and the physical characteristics of the radiation mechanism, the magnetic field and the density of flares more directly.' The observations provide a deeper look at how the black hole's activity varies in brightness over time, said Tuan Do, associate professor in the physics and astronomy department and deputy director of the Galactic Center Group at UCLA. Do was not involved in this study but has led research on Sagittarius A* in the past, including when the black hole showcased unusual activity in 2019. 'Sgr A* got about half as bright in the new data as was seen in 2019, so I think that 2019 is still unusually active for the black hole,' Do said. 'The black hole and its environment (are) always changing though so we are never sure what we'll find! This is what makes observations of the galactic center so exciting, even though we've stared at this spot in the sky for decades now.' When the authors of the latest study observed the two different wavelengths of light from the black hole simultaneously, they realized the shorter wavelength changed in brightness just before the longer wavelength. The observation suggested that as the particles spiral around magnetic field lines, they lose energy more quickly. The changes in brightness have been noted in previous research and recent complementary data from the Mid-Infrared Instrument on the Webb telescope and other observatories. 'I think the next big step would be to try to connect these different data sources together to form a fuller picture of the physics of the environment around the supermassive black hole,' Do said. The new study also confirms the black hole has 'non-stop variability,' as previously observed, said Mark Morris, distinguished research professor in the department of physics and astronomy at UCLA. Morris was not involved in the new study. 'X-ray astronomers see reasonably strong evidence that in the last few hundred years, there has been at least one, maybe two instances of enormous flares taking place,' Morris said via email, 'with intensities (10,000 to 100,000) times larger than anything we've seen in the last quarter century that we have been closely examining Sgr A*.' What might have caused these flares? Astronomers still don't know, but it's possible the black hole gobbled up a planet a few hundred years ago, Morris said. When the sun releases solar storms, scientists worry because such activity can potentially affect GPS, communications and the power grid on Earth. But at 25,000 light-years away, the highly energetic and variable activity of the Milky Way's central black hole isn't a concern, Morris said. However, the Webb telescope observations allow researchers to understand what kind of 'storms' are created when matter is compressed and heated as it is drawn toward the black hole. 'Beyond pure interest in the most dazzling fireworks that the universe can produce, those fireworks can have a profound effect on the evolution of the galaxies that they are in,' Morris said. 'They can provoke or impede star formation on large scales, they can remove gas and clear out galaxies, leaving them unable to form stars.' The study authors don't believe the black hole was experiencing an unusual spike in activity, but they want to observe Sagittarius A* for an uninterrupted 24 hours to be sure. 'We also can see if these flares show periodicity (or repeat themselves) or if they are truly random,' Yusef-Zadeh said. Astronomers still don't know how fast Sagittarius A* is spinning as it gobbles up matter, but longer observations could provide the data necessary to find the answer. Ultimately, more data from Webb observations of Sagittarius A* could help astronomers simulate how accretion disks behave around black holes, as well as comparing the behaviors of less energetically active, black holes with more active ones.
