Astronomers Spy Quartet of Cavities From Giant Black Holes

Optical & X-ray Images of  RBS 797, side-by-side
Galaxy Cluster RBS 797
Credit: X-ray: NASA/CXC/Univ. of Bologna/F. Ubertosi; Optical: NASA/STScl/M.Calzadilla

Four enormous cavities, or bubbles, have been found at the center of a galaxy cluster using NASA's Chandra X-ray Observatory, as described in our latest press release. The left panel of this graphic shows an optical image of the galaxy cluster called RBS 797, from NASA's Hubble Space Telescope. Hot gas that envelopes the individual galaxies is invisible in optical light, but it is detected in X-rays by Chandra (right). One pair of cavities can be seen towards the left and right of center in the Chandra image as black oval-shaped regions. The other pair is less distinct, but can be found above and below the center of the image.

Planetary Nebula: Misnamed But Not Misunderstood

Image of six different planetary nebulas
Planetary Nebulas: NGC 6302, IC 418, NGC 3242, NGC 7662, NGC 7027, and NGC 2371.
Credit: X-ray: NASA/CXC/RIT/SAO/J.Kastner; Optical: NASA/ESA/AURA/STScI/Univ. Washington, B.Balick

Sometimes the names of objects are deeply misleading. For example, starfish are not actually fish (they are echinoderms) and guinea pigs are not related to pigs in any way (they are rodents). Similarly, planetary nebulas have nothing to do with planets. They were misnamed when scientists looking through small telescopes in the 19th century thought that these objects looked like planets.

Today, astronomers know that a planetary nebula actually represents a phase that stars like our Sun experience after they use up much of their fuel. After cooling and expanding through a “red giant” phase when it begins to expel its outer layers, such a star leaves behind a type of dense and smaller star called a white dwarf. The previously jettisoned shells of gas remain for a relatively short time in cosmic terms — tens of thousands of years — before dissipating into space. Meanwhile they are illuminated and energized by the white dwarf at the center of the system. This will happen to our Sun, but not for another 5 billion years or so.

Roasted and Shredded by a Stellar Sidekick

Inset X-ray image of KPD 0005+5106 within an illustration
White Dwarf KPD 0005+5106
Credit: Illustration: NASA/CXC/M. Weiss; X-ray (Inset): NASA/CXC/ASIAA/Y.-H. Chu, et al.

A team of scientists used NASA's Chandra X-ray Observatory and ESA's XMM-Newton to investigate some unusual X-ray activity of a white dwarf star, as reported in our latest press release. The data suggest this white dwarf is blasting a companion object, which is either a low-mass star or planet, with waves of heat and radiation while pulling it apart through gravitational force.

Most stars, including the Sun, will become "white dwarfs" after they begin to run out of fuel, expand and cool into a red giant, and then lose their outer layers. This evolution leaves behind a stellar nub that slowly fades for billions of years. An artist's illustration shows a white dwarf as the blue-white sphere near the center.

From High School to a High-Energy Discovery

Image of Julia Berndtsson with a mountainscape in the background
Julia Berndtsson

This blog post was written by Julia Berndtsson, a Swedish physics student currently in the third year of her undergraduate studies at Princeton University in the United States. For our latest Chandra result, she collaborated with Rosanne Di Stefano at the Center for Astrophysics | Harvard & Smithsonian during her last year of high school and through the first half of her freshman year at Princeton. She is currently exploring a range of topics in physics and engineering and works with Jason Petta's group at Princeton on developing semiconducting qubits.

When one imagines a scientist, a high school student usually isn’t the first thing that comes to mind. What people may or may not know is that there are multiple summer programs aimed at students still in their secondary education to gain exposure to research in their natural sciences, and it is because of such a program I ended up joining Dr. Rosanne Di Stefano in writing a paper on the discovery of the first planet candidate in an external galaxy.

The summer before my senior year, I was admitted to the Center for Excellence in Education’s Research Science Institute where participants were matched with a research mentor and given a project to be carried out over six weeks. Meeting Rosanne for the first time had me in awe. Not only did she give the students she took on her full confidence, but she would talk with excitement both about the topics that we were examining and over the fact that you were there to work on these problems too.

Behind the Story of the First Extragalactic Exoplanet Candidate

Image of Rosanne DiStefano in front of bushes
Rosanne DiStefano

We welcome Rosanne Di Stefano, an astrophysicist at the Center for Astrophysics | Harvard & Smithsonian, as our guest blogger. Her work has encompassed a broad range of astronomical systems: stars interacting within dense stellar environments, the binary evolution of possible progenitors of Type Ia supernovae, X-ray astronomy, and gravitational microlensing. In this post, she writes about her team’s finding of a possible planet candidate in M51, which is featured in our latest press release.

The discovery of a candidate planet in M51 (nicknamed the “Whirlpool” galaxy) represents several firsts. Perhaps most important, it is the first candidate planet in a distant galaxy. Since the 1750s, it has been conjectured that the dim distant nebulas, now called galaxies, are island universes: large, gravitationally-bound stellar populations similar to our home, the Milky Way. Since the work of Edwin Hubble in 1929, we have been able to study stars in other galaxies. Our discovery of the planet candidate — in a binary system called M51 ULS-1 — gives us the first peek into external populations of planetary systems, extending the reach of planet searches to distances roughly ten thousand times more distant.

The candidate planet is understood to be in the “circumbinary” orbit of a compact object (either a neutron star or a black hole) and a donor star, meaning that the donor and compact orbit one another and that the candidate planet orbits the mass center of these two. (We call it a “donor” star because the compact object is pulling material from its surface and into a disk around the neutron star or black hole.) This makes the planet candidate in M51 ULS-1 the first found to be orbiting a high-mass star. In our own Galaxy, astronomers have discovered more than 4800 planets, but the stars they orbit are less massive than about four times the mass of our own Sun. Stars can be very much more massive, however. While the exact value of the largest possible stellar mass in today’s Universe remains uncertain, it is at least 100 solar masses. The donor star in M51 ULS-1 appears to have the luminosity and spectrum of a 20 to 30 solar mass star.

When a Stable Star Explodes

Image of G344.7
Supernova Remnant G344.7-0.1
Credit: X-ray: NASA/CXC/Tokyo Univ. of Science/K. Fukushima, et al.; IR: NASA/JPL/Spitzer; Radio: CSIRO/ATNF/ATCA

White dwarfs are among the most stable of stars. Left on their own, these stars that have exhausted most of their nuclear fuel — while still typically as massive as the Sun — and shrunk to a relatively small size can last for billions or even trillions of years.

However, a white dwarf with a nearby companion star can become a cosmic powder keg. If the companion's orbit brings it too close, the white dwarf can pull material from it until the white dwarf grows so much that it becomes unstable and explodes. This kind of stellar blast is called a Type Ia supernova.

While it is generally accepted by astronomers that such encounters between white dwarfs and "normal" companion stars are one likely source of Type Ia supernova explosions, many details of the process are not well understood. One way to investigate the explosion mechanism is to look at the elements left behind by the supernova in its debris or ejecta.

Why Make Sonifications of Astronomical Data?

3 images of the objects sonified in this edition
Jingle, Pluck, and Hum: Sounds from Space
Credit: NASA/CXC/SAO/K.Arcand, SYSTEM Sounds (M. Russo, A. Santaguida)

When you travel to a foreign country where they speak a language you do not understand, it is usually imperative that you find a way to translate what is being communicated to you. In some respects, the same can be said about data collected from objects in space.

A telescope like NASA's Chandra X-ray Observatory captures X-rays, which are invisible to the human eye, from sources across the cosmos. This high-energy light gets sent back down to Earth in the form of ones and zeroes. From there, the data are transformed into a variety of different things — from plots to spectra to images.

This last category — images — is arguably what most telescopes are best known for. For most of astronomy's long history, however, most who are blind or visually impaired (BVI) can often not fully experience the wonders that telescopes have captured.

In recent decades, that has begun to change. There are various ways that astronomers, data scientists, astronomy communication professionals, and others can work with communities of different abilities, from creating 3D prints and visual descriptions to sound-based products. As part of the Chandra X-ray Center and NASA's Universe of Learning, a team of experts led by Dr. Kimberly Arcand has been working to "sonify" (turn into sound) data from some of NASA's greatest telescopes.

"X-ray Magnifying Glass" Enhances View of Distant Black Holes

X-ray image and illustration of MG B2016+112
Gravitationally-Lensed System MG B2016+112
Credit: Illustration: NASA/CXC/M. Weiss; X-ray (inset): NASA/CXC/SAO/D. Schwartz et al.

A new technique using NASA's Chandra X-ray Observatory has allowed astronomers to obtain an unprecedented look at a black hole system in the early Universe, as reported in our latest press release. This is providing a way for astronomers to look at faint and distant X-ray objects in more detail than had previously been possible.

Astronomers used an alignment in space that shows "gravitational lensing" of light from two objects that are nearly 12 billion light years away. An artist's illustration in the main part of this graphic shows how the paths of light from these distant objects are bent and amplified by a galaxy along the line of sight between Earth and the objects.

Huge Rings Around a Black Hole

Image of V404 Cygni
V404 Cygni
Credit: X-ray: NASA/CXC/U.Wisc-Madison/S. Heinz et al.; Optical/IR: Pan-STARRS

This image features a spectacular set of rings around a black hole, captured using NASA's Chandra X-ray Observatory and Neil Gehrels Swift Observatory. The X-ray images of the giant rings reveal information about dust located in our galaxy, using a similar principle to the X-rays performed in doctor's offices and airports.

The black hole is part of a binary system called V404 Cygni, located about 7,800 light years away from Earth. The black hole is actively pulling material away from a companion star — with about half the mass of the Sun — into a disk around the invisible object. This material glows in X-rays, so astronomers refer to these systems as "X-ray binaries."

Chandra Catches Slingshot During Collision

Multiwavelength Image of Abell 1775
Abell 1775
Credit: X-ray: NASA/CXC/Leiden Univ./A. Botteon et al.; Radio: LOFAR/ASTRON; Optical/IR:PanSTARRS

When the titans of space — galaxy clusters — collide, extraordinary things can happen. A new study using NASA's Chandra X-ray Observatory examines the repercussions after two galaxy clusters clashed.

Galaxy clusters are the largest structures in the Universe held together by gravity, containing hundreds or even thousands of individual galaxies immersed in giant oceans of superheated gas. In galaxy clusters, the normal matter — like the atoms that make up the stars, planets, and everything on Earth — is primarily in the form of hot gas and stars. The mass of the hot gas between the galaxies is far greater than the mass of the stars in all of the galaxies. This normal matter is bound in the cluster by the gravity of an even greater mass of dark matter.

Because of the huge masses and speeds involved, collisions and mergers between galaxy clusters are among the most energetic events in the universe.

In a new study of the galaxy cluster Abell 1775, located about 960 million light years from Earth, a team of astronomers led by Andrea Botteon from Leiden University in the Netherlands announced that they found a spiral-shaped pattern in Chandra's X-ray data. These results imply a turbulent past for the cluster.

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