NASA’s Chandra Notices the Galactic Center is Venting

NASA’s Chandra Notices the Galactic Center is Venting

X-ray: NASA/CXC/Univ. of Chicago/S.C. Mackey et al.; Radio: NRF/SARAO/MeerKAT; Image Processing: NASA/CXC/SAO/N. Wolk

These images show evidence for an exhaust vent attached to a chimney releasing hot gas from a region around the supermassive black hole at the center of the Milky Way, as reported in our latest press release. In the main image of this graphic, X-rays from NASA’s Chandra X-ray Observatory (blue) have been combined with radio data from the MeerKAT telescope (red).

Previously, astronomers had identified a “chimney” of hot gas near the Galactic Center using X-ray data from Chandra and ESA’s XMM-Newton. Radio emission detected by MeerKAT shows the effect of magnetic fields enclosing the gas in the chimney.

The evidence for the exhaust vent is highlighted in the inset, which includes only Chandra data. Several X-ray ridges showing brighter X-rays appear in white, roughly perpendicular to the plane of the Galaxy. Researchers think these are the walls of a tunnel, shaped like a cylinder, which helps funnel hot gas as it moves upwards along the chimney and away from the Galactic Center.

A labeled version of the image gives the locations of the exhaust vent, the chimney, the supermassive black hole at the center of the Milky Way Galaxy (called Sagittarius A*, or Sgr A* for short) and the plane of the galaxy.

Chandra data reveal several X-ray ridges that astronomers think are the walls of a tunnel, shaped like a cylinder, which helps funnel hot gas as it moves away from the Galactic Center. This “exhaust vent” is connected to a previously-discovered “chimney” and helps release hot gas generated by the supermassive black hole at the Galactic Center. In this image, Chandra’s X-rays are shown with radio data from MeerKAT to demonstrate the chimney and vent, with a closer-in view of the exhaust vent as well. The supermassive black hole is near the bottom of the image.
X-ray: NASA/CXC/Univ. of Chicago/S.C. Mackey et al.; Radio: NRF/SARAO/MeerKAT; Image Processing: NASA/CXC/SAO/N. Wolk

This newly discovered vent is located near the top of the chimney about 700 light-years from the center of the Galaxy. To emphasize the chimney and exhaust vent features the image has been rotated by 180 degrees from the conventional orientation used by astronomers, so that the chimney is pointed upwards.

The authors of the new study think that the exhaust vent formed when hot gas rising through the chimney struck cooler gas lying in its path. The brightness of the exhaust vent walls in X-rays is caused by shock waves — similar to sonic booms from supersonic planes — generated by this collision. The left side of the exhaust vent is likely particularly bright in X-rays because the gas flowing upwards is striking the tunnel wall at a more direct angle and with more force than other regions.

The researchers determined that the hot gas is most likely coming from a sequence of events involving material falling towards Sgr A*. They think eruptions from the black hole then drove the gas upwards along the chimneys, and out through the exhaust vent.

It is unclear how often material is falling onto Sgr A*. Previous studies have indicated that dramatic X-ray flares take place every few hundred years at or near the location of the central black hole, so those could play important roles in driving the hot gas upwards through the exhaust vent. Astronomers also estimate that the Galactic black hole rips apart and swallows a star every 20,000 years or so. Such events would lead to powerful, explosive releases of energy, much of which would be destined to rise through the chimney vent.

The paper describing these results is published in The Astrophysical Journal and a preprint is available online. The authors of the paper are Scott Mackey (University of Chicago), Mark Morris (University of California, Los Angeles), Gabriele Ponti (Italian National Institute of Astrophysics in Merate ), Konstantina Anastasopoulou (Italian National Institute of Astrophysics in Palermo), and Samaresh Mondal (Italian National Institute of Astrophysics in Merate).

NASA’s Marshall Space Flight Center manages the Chandra program. The Smithsonian Astrophysical Observatory’s Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.

Read more from NASA’s Chandra X-ray Observatory.

For more Chandra images, multimedia and related materials, visit:

https://www.nasa.gov/mission/chandra-x-ray-observatory/

Visual Description:

This image shows a region near the center of our Milky Way galaxy in X-ray and radio light. At the bottom of the image, near the center, is a brilliant, tangled knot of material that resembles a paint splatter. This is the brightest region in the image, and it contains the supermassive black hole at center of our galaxy, known as Sagittarius A*.

The lower third of the image resembles an angry firestorm. Streaks of red and orange are scattered in every direction, as if a legion of embers from a fire crackled and popped into the air all at once. Flame-like structures lick toward the center from our right.

Much of the image is infused with wispy blue clouds showing X-rays detected by Chandra. At a few points, the wispy blue clouds seem to form into balls of teal colored light and are known as dust halos. They are caused by X-rays from bright X-ray sources reflecting off dust surrounding the sources. These dust halos resemble underwater lights glowing in a cloudy swimming pool at night.

Rising up from Sagittarius A* in the center of the image is a pillar of blue light referred to as a chimney. This chimney of hot gas is surrounded by red clouds that are filled with stars, presenting themselves as tiny red flecks. Near the top of the blue pillar is a streak of light blue, outlined by an illustrated, gray box. This streak is referred to as the chimney exhaust vent. Just to our left is another illustrated box that shows the close-up image of the chimney vent as observed by Chandra.

News Media Contact

Megan Watzke
Chandra X-ray Center
Cambridge, Mass.
617-496-7998

Jonathan Deal
Marshall Space Flight Center
Huntsville, Ala.
256-544-0034

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Lee Mohon

NASA Administrator to Engage Officials in Italy, Vatican, Saudi Arabia

NASA Administrator to Engage Officials in Italy, Vatican, Saudi Arabia

NASA Administrator Bill Nelson gives remarks during a NASA town hall event, Tuesday, Dec. 12, 2023, at NASA Headquarters in Washington.
Credits: NASA/Bill Ingalls

Continuing his engagement to deepen international collaboration and the peaceful use of space, NASA Administrator Bill Nelson will travel to Italy and Vatican City, followed by Saudi Arabia, beginning Thursday.

Nelson will meet with key government and space officials in each country.

Italy is a longstanding partner in human spaceflight and Earth science. Nelson will meet with President Teodoro Valente, Italian Space Agency (ASI) and other officials to discuss current and future collaboration, including the Artemis campaign to return to the Moon, partnership on the International Space Station, the exploration of Mars and Venus, and Earth science missions to study our home planet.

In Saudi Arabia, Nelson will meet with Saudi Space Agency and other senior officials to discuss future collaboration and underscore the importance of civil space cooperation for the broader United States and Saudi Arabia relationship. Students will interact with Nelson about the importance of science, technology, engineering, and mathematics education and their roles as members of the Artemis Generation.

For more information about NASA’s international partnerships, visit:

https://www.nasa.gov/oiir/

-end-

Faith McKie
Headquarters, Washington
202-358-1600
faith.d.mckie@nasa.gov

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Lauren E. Low

NASA Licenses 3D-Printable Superalloy to Benefit US Economy

NASA Licenses 3D-Printable Superalloy to Benefit US Economy

3 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

NASA superalloy GRX-810 will soon be available to aviation and space industry parts manufacturers as a result of new licensing agreements with four U.S. companies.
Credit: NASA/Jef Janis

NASA’s investment in a breakthrough superalloy developed for the extreme temperatures and harsh conditions of air and spaceflight is on the threshold of paying commercial dividends.

The agency is licensing its invention, dubbed “GRX-810,” to four American companies, a practice that benefits the United States economy as a return on investment of taxpayer dollars.

GRX-810 is a 3D-printable high-temperature material that will lead to stronger, more durable airplane and spacecraft parts that can withstand more punishment before reaching their breaking point.

The co-exclusive license agreements will allow the companies to produce and market GRX-810 to airplane and rocket equipment manufacturers as well as the entire supply chain.

The four co-exclusive licensees are:

  • Carpenter Technology Corporation of Reading, Pennsylvania
  • Elementum 3D, Inc. of Erie, Colorado
  • Linde Advanced Material Technologies, Inc. of Indianapolis
  • Powder Alloy Corporation of Loveland, Ohio

GRX-810 is one example of many new technologies NASA’s Technology Transfer Program managers review and file for patent protection. The team also works with inventors to find partners interested in commercialization. 

“NASA invests tax dollars into research that demonstrates direct benefit to the U.S. and transfers its technologies to industry by licensing its patents,” said Amy Hiltabidel, licensing manager at NASA’s Glenn Research Center in Cleveland.

New Approach to Developing Materials

NASA engineers designed GRX-810 for aerospace applications, including liquid rocket engine injectors, combustors, turbines, and hot-section components capable of enduring temperatures over 2,000 degrees Fahrenheit.

“GRX-810 represents a new alloy design space and manufacturing technique that was impossible a few years ago,” said Dr. Tim Smith, materials researcher at NASA Glenn.

Smith co-invented the superalloy along with his Glenn colleague Christopher Kantzos using a time-saving computer modeling and laser 3D-printing process that fuses metals together, layer-by-layer. Tiny particles containing oxygen atoms spread throughout the alloy enhance its strength.

Impacts and Benefits

Compared to other nickel-base alloys, GRX-810 can endure higher temperatures and stress and can last up to 2,500 times longer. It’s also nearly four times better at flexing before breaking and twice as resistant to oxidation damage.

Adoption of this alloy will lead to more sustainable aviation and space exploration,” said Dale Hopkins, deputy project manager of NASA’s Transformational Tools and Technologies project. “This is because jet engine and rocket components made from GRX-810 will lower operating costs by lasting longer and improving overall fuel efficiency.”

Research and development teams include those from Glenn, NASA’s Ames Research Center in California’s Silicon Valley, The Ohio State University, and NASA’s Marshall Space Flight Center in Huntsville, Alabama, where the most recent testing included 3D-printed rocket engine parts.

NASA develops many technologies to solve the challenges of space exploration, advance the understanding of our home planet, and improve air transportation. Through patent licensing and other mechanisms, NASA has spun off more than 2,000 technologies for companies to develop into products and solutions supporting the American economy.

A NASA insignia, also known as the meatball, is being 3D printed and appears to be green in its printing chamber with a bright laser flash in the upper right-hand corner.
The NASA insignia is 3D printed using the GRX-810 superalloy.
Credit: NASA/Jordan Salkin

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Kelly M. Matter

Sols 4180-4182: Imaging fest!

Sols 4180-4182: Imaging fest!

3 min read

Sols 4180-4182: Imaging fest!

NASA's Mars rover Curiosity acquired this image using its Mars Hand Lens Imager (MAHLI), located on the turret at the end of the rover's robotic arm, on May 7, 2024, Sol 4178 of the Mars Science Laboratory Mission, at 23:20:40 UTC.
This Mars Hand Lens Imager (MAHLI) image shows all the features and textures we have in the area ranging from laminae to little nodules. The image was taken on May 7, 2024, Sol 4178 of the Mars Science Laboratory Mission, at 23:20:40 UTC.
NASA/JPL-Caltech/MSSS

Earth planning date: Wednesday, May 8, 2024

What a wonderful sight to see all the sedimentary structures. I am a geochemist, but I hear the excitement in the voices of my sediment-specialist colleagues, discussing all those textures and things to see. Generally, it is those features that allow us to determine what has happened in terms of the physics: Was it water or wind that brought the grains here? How fast was the flow? And then… what happened next? Well, that might be in my area of expertise, as it takes new minerals to grow between grains to make a loose sediment into a rock. And that’s what we can learn from the chemical investigations. And today’s plan once again has it all, but it is especially an imaging fest looking at all the structures and textures. Stay tuned for the images to make their way from Mars to Earth in the coming days.

Today’s plan starts with the chemistry: APXS will use the cool hours of the early morning for its investigations on the brushed target “Happy Isles.” MAHLI will get images of Happy Isles and then move to start the imaging fest at a target named “Laurel Mountain.” This is to peak underneath a piece of overhanging rock to see how the layers below are actually connected – or not – to the layers that form the overhang. Spying on rocks? I guess so!

The imaging fest then continues with over 170 Mastcam frames divided into four investigations. These are mosaics on the surrounding hills and slopes, namely on “Pinnacle Ridge,” “Milestone Peak” and “Tamarack Flats.” And Mastcam looks at the area closer to the rover, off the starboard side, an area where all the structures I talked about above are nicely visible from the rover mast’s vantage point. And if that’s not enough imaging, we will add some special imaging after the drive. We always take navigation camera images for navigation and imaging purpose during the next planning, but this time, we will also take additional Mastcam images in the drive direction. It’s a complex landscape … and I am still happy I can watch the rover drive through it and don’t have to hike myself!

There are also plenty of environmental investigations in the plan. The atmospheric investigations include the usual cadence of REMS activities and DAN looks at the water in the subsurface with passive measurements. In addition to that, Curiosity will look at its top surface to look at the dust levels currently accumulated there, and a look to the crater rim will investigate the current opacity of the atmosphere (yes, that’s more images, too!). Finally, Curiosity will be on the lookout for some dust devils. We’ve managed to get a few really nice captures of those in the course of the mission, one of my favourites is this one here, taken on sol 2847, over 1300 sols ago! If you want to see some in motion, here you go: https://www.youtube.com/watch?v=k8lfJ0c7WQ8. Time flies when you are having fun!

Written by Susanne Schwenzer, Planetary Geologist at The Open University

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May 08, 2024

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Sols 4178-4179: The Pinnacle Ridge Scarp

Sols 4178-4179: The Pinnacle Ridge Scarp

2 min read

Sols 4178-4179: The Pinnacle Ridge Scarp

This image was taken by Left Navigation Camera onboard NASA's Mars rover Curiosity on Sol 4176 (2024-05-05 22:50:10 UTC).
This image was taken by Left Navigation Camera onboard NASA’s Mars rover Curiosity on Sol 4176 (2024-05-05 22:50:10 UTC).
NASA/JPL-Caltech

Earth planning date: Monday, May 6, 2024

Curiosity’s set of complex activities and drive over the weekend executed perfectly and we started our planning today directly in front of a scarp, or wall, along a section of the upper Gediz Valis ridge known as “Pinnacle Ridge.” The view along this scarp did not disappoint! 

Mastcam planned a large mosaic to image the top and bottom of the Pinnacle Ridge scarp, complementing the Mastcam mosaic that was acquired over the weekend. ChemCam included a long distance RMI image of the face of the ridge with intriguing tonal and textural variations. The targeted science block on sol 4178 also includes a MAHLI mosaic of an interesting layered rock in our workspace, “El Portal,” that will be characterized and imaged by ChemCam LIBS and Mastcam. Lastly, Mastcam will take a small mosaic of a rock in the workspace, “Bairs Creek,” to investigate interesting textures and features that were created by the wind. 

In the untargeted science block on sol 4179, the environmental theme group planned several activities including a Mastcam sky survey, a dust devil movie and survey, and a suprahorizon movie to observe dust and cloud activity in Gale. ChemCam included an AEGIS activity where the rover will pick and analyze a target in the workspace after Curiosity completes a ~32-meter drive. Although the large, tilted rocks ahead make for a challenging drive, excitement is running high as we continue our ascent along the margin of the upper Gediz Vallis ridge!

Written by Sharon Wilson Purdy, Planetary Geologist at Smithsonian National Air and Space Museum

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May 08, 2024

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