NuSTAR catches black holes in galaxy web
The orbiting telescope is giving scientists a wealth of new information on a wide array of cosmic phenomena in the high-energy X-ray portion of the electromagnetic spectrum.
January 8, 2013
NASA’s Nuclear Spectroscopic Telescope Array (NuSTAR) set its X-ray eyes on a spiral galaxy and caught the brilliant glow of two black holes lurking inside.
This new view of spiral galaxy IC 342 (Caldwell 5) includes data from NASA's Nuclear Spectroscopic Telescope Array (NuSTAR). High-energy X-ray data from NuSTAR have been translated to the color magenta and superimposed on a visible-light view highlighting the galaxy and its star-studded arms. NuSTAR is the first orbiting telescope to take focused pictures of the cosmos in high-energy X-ray light. Previous observations of this same galaxy taken at similar wavelengths blurred the entire object into one pixel. // Credit: NASA/JPL-Caltech/DSS
“These new images showcase why NuSTAR is giving us an unprecedented look at the cosmos,” said Lou Kaluzienski from NASA Headquarters in Washington, D.C. “With NuSTAR’s greater sensitivity and imaging capability, we’re getting a wealth of new information on a wide array of cosmic phenomena in the high-energy X-ray portion of the electromagnetic spectrum.”
Launched last June, NuSTAR is the first orbiting telescope with the ability to focus high-energy X-ray light. It can view objects in considerably greater detail than previous missions operating at similar wavelengths. Since launch, the NuSTAR team has been fine-tuning the telescope, which includes a mast the length of a school bus connecting the mirrors and detectors.
The mission has looked at a range of extreme high-energy objects already, including black holes near and far, and the incredibly dense cores of dead stars. In addition, NuSTAR has begun black hole searches in the inner region of the Milky Way Galaxy and in distant galaxies in the universe.
Among the telescope’s targets is the spiral galaxy IC 342, also known as Caldwell 5, featured in one of the new images. This galaxy lies 7 million light-years away in the constellation Camelopardalis the Giraffe. Previous X-ray observations of the galaxy from NASA’s Chandra X-ray Observatory revealed the presence of two blinding black holes called ultraluminous X-ray sources (ULXs).
How ULXs can shine so brilliantly is an ongoing mystery in astronomy. While these black holes are not as powerful as the supermassive black hole at the hearts of galaxies, they are more than 10 times brighter than the stellar-mass black holes peppered among the stars in our own galaxy. Astronomers think ULXs could be less common intermediate-mass black holes, with a few thousand times the mass of our Sun, or smaller stellar-mass black holes in an unusually bright state. A third possibility is that these black holes don’t fit neatly into either category.
This new view of the historical supernova remnant Cassiopeia A, located 11,000 light-years away, was taken by NASA's NuSTAR. Blue indicates the highest energy X-ray light, where NuSTAR has made the first resolved image ever of this source. Red and green show the lower end of NuSTAR's energy range, which overlaps with NASA's high-resolution Chandra X-ray Observatory. // Credit: NASA/JPL-Caltech/DSS
“High-energy X-rays hold a key to unlocking the mystery surrounding these objects,” said Fiona Harrison of the California Institute of Technology in Pasadena. “Whether they are massive black holes or there is new physics in how they feed, the answer is going to be fascinating.”
In the image, the two bright spots that appear entangled in the arms of the IC 342 galaxy are the black holes. High-energy X-ray light has been translated into the color magenta, while the galaxy itself is shown in visible light.
“Before NuSTAR, high-energy X-ray pictures of this galaxy and the two black holes would be so fuzzy that everything would appear as one pixel,” said Harrison.
The second image features the well-known, historical supernova remnant Cassiopeia A, located 11,000 light-years away in the constellation Cassiopeia. The color blue indicates the highest-energy X-ray light seen by NuSTAR, while red and green signify the lower end of NuSTAR’s energy range. The blue region is where the shock wave from the supernova blast is slamming into material surrounding it, accelerating particles to nearly the speed of light. As the particles speed up, they give off a type of light known as synchrotron radiation. NuSTAR will be able to determine for the first time how energetic the particles are and address the mystery of what causes them to reach such great speeds.
“Cas A is the poster child for studying how massive stars explode and also provides us a clue to the origin of the high-energy particles, or cosmic rays, that we see here on Earth,” said Brian Grefenstette of Caltech. “With NuSTAR, we can study where, as well as how, particles are accelerated to such ultra-relativistic energies in the remnant left behind by the supernova explosion.”