Images by Date
Images by Category
Solar System
Stars
Exoplanets
White Dwarfs
Supernovas
Neutron Stars
Black Holes
Milky Way Galaxy
Normal Galaxies
Quasars
Galaxy Clusters
Cosmology/Deep Field
Miscellaneous
Images by Interest
Space Scoop for Kids
4K JPG
Multiwavelength
Sky Map
Constellations
Photo Blog
Top Rated Images
Image Handouts
Desktops
Fits Files
Visual descriptions
Image Tutorials
Photo Album Tutorial
False Color
Cosmic Distance
Look-Back Time
Scale & Distance
Angular Measurement
Images & Processing
AVM/Metadata
Image Use Policy
Web Shortcuts
Chandra Blog
RSS Feed
Chronicle
Email Newsletter
News & Noteworthy
Image Use Policy
Questions & Answers
Glossary of Terms
Download Guide
Get Adobe Reader
47 Tucanae: Probing Extreme Matter Through Observations of Neutron Stars

  • One of the most reliable estimates of the relation between the radius of a neutron star and its mass has been made.

  • Neutron stars are the ultra-dense cores often left behind when massive stars collapse.

  • They contain the densest matter in the Universe outside of black holes.

  • Data from Chandra and other X-ray telescopes were used to understand more about the interior structure of neutron stars.

Neutron stars, the ultra-dense cores left behind after massive stars collapse, contain the densest matter known in the Universe outside of a black hole. New results from Chandra and other X-ray telescopes have provided one of the most reliable determinations yet of the relation between the radius of a neutron star and its mass. These results constrain how nuclear matter - protons and neutrons, and their constituent quarks - interact under the extreme conditions found in neutron stars.

Three telescopes - Chandra, ESA's XMM-Newton, and NASA's Rossi X-ray Timing Explorer (RXTE) - were used to observe 8 neutron stars, including one in 47 Tucanae, a globular cluster located about 15,000 light years away in the outskirts of the Milky Way. The image shown here was constructed from a long Chandra observation of 47 Tucanae. Lower-energy X-rays are red, X-rays with intermediate energies are green, and the highest-energy X-rays are shown in blue.

In the image, the double, or binary, star system labeled as X7 contains a neutron star slowly pulling gas away from a companion star with a mass much lower than the Sun. In 2006, researchers used observations of the amount of X-rays from X7 at different energies together with theoretical models to determine a relationship between the mass and the radius of the neutron star. A similar procedure was used for Chandra observations of a neutron star in another globular cluster, NGC 6397, and for two other neutron stars in clusters observed by ESA's XMM-Newton.

Four other neutron stars were observed with RXTE to undergo bursts of X-rays that cause the atmosphere of the neutron star to expand. By following the cooling of the star, its surface area can be calculated. Then, by folding in independent estimates of the distance to the neutron star, scientists were able to gather more information on the relationships between the masses and radii of these neutron stars.

Because the mass and radius of a neutron star is directly related to interactions between the particles in the interior of the star, the latest results give scientists new information about the inner workings of neutron stars.

The researchers used a wide range of different models for the structure of these collapsed objects and determined that the radius of a neutron star with a mass that is 1.4 times the mass of the Sun is between 10.4 and 12.9 km (6.5 to 8.0 miles). They also estimated the density at the center of a neutron star was about 8 times that of nuclear matter found in Earth-like conditions. This translates into a pressure that is over ten trillion trillion times the pressure required for diamonds to form inside the Earth.

The results apply whether the entire set of bursting sources, or the most extreme of the other sources, are removed from the sample. Previous studies have used smaller samples of neutron stars or have not accounted for as many uncertainties in using the models.

The new values for the neutron star's structure should hold true even if matter composed of free quarks exists in the core of the star. Quarks are fundamental particles that combine to form protons and neutrons and are not usually found in isolation. It has been postulated that free quarks may exist inside the centers of neutron stars, but no firm evidence for this has ever been found.

The researchers also made an estimate of the distances between neutrons and protons in atomic nuclei here on earth. A larger neutron star radius naturally implies that, on average, neutrons and protons in a heavy nucleus are farther apart. Their estimate is being compared with values from terrestrial experiments.

The neutron star observations also provided new information about the so-called "symmetry energy" for nuclear matter, which is the energy cost required to create a system with a different number of protons than neutrons. The symmetry energy is important for neutron stars because they contain almost ten times as many neutrons as protons. It is also important for heavy atoms on Earth, like Uranium, because they often have more neutrons than protons. The results show that the symmetry energy does not change much with density.

These results will be published in a paper in the March 1st, 2013 issue of The Astrophysical Journal Letters. The authors are Andrew Steiner, from the Institute for Nuclear Theory at the University of Washington, James Lattimer from Stony Brook University in New York and Edward Brown from Michigan State University.

NASA's Marshall Space Flight Center in Huntsville, Ala., manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory controls Chandra's science and flight operations from Cambridge, Mass.

Fast Facts for 47 Tucanae:
Credit  NASA/CXC/Michigan State/A.Steiner et al
Release Date  March 6, 2013
Scale  Image is 2.3 arcmin across (about 10 light years)
Category  Neutron Stars/X-ray Binaries
Coordinates (J2000)  RA 00h 24m 05s | Dec -72° 04´ 53"
Constellation  Tucana
Observation Date  13 pointings between March 16, 2000 and Oct 11, 2002
Observation Time  100 (4 days, 4 hours).
Obs. ID  78, 953-956, 2735-2738, 3384-3387
Instrument  ACIS
References Steiner, A. et al 2013, ApJ 765, L5; arXiv:1205.6871
Color Code  X-ray (Red, Green, Blue)
X-ray
Distance Estimate  14,800 light years
distance arrow
Visitor Comments (4)

Thanks, it's really informatics I mean I didn't know there are stars that have more neutrons than protons. Awesome.

Posted by NASAFan on Tuesday, 07.1.14 @ 07:56am


Thank you. It is very informatics. I like neutron stars. Photo above is awesome.

Posted by Shahzad Gohar on Saturday, 03.29.14 @ 10:34am


I like it. Very informative for me. Thank you.
Oscar
Argentina

Posted by Chuf on Friday, 03.15.13 @ 13:43pm


Thank you for the info. I am very interested in anything related to astronomy. I had forgotten Kepler's 3rd Law it was good to see it again and use it.

Posted by Boyd Corcoran on Thursday, 03.14.13 @ 16:36pm


Rate This Image

Rating: 3.8/5
(1178 votes cast)
Download & Share

Desktops

1024x768 - 341.7 kb
1280x1024 - 513.6 kb
1680x1050 - 712 kb
More Information
For Kids: 47 Tucanae
Blog: 47 Tucanae
More Images
X-ray Image of
NGC 6397
Jpg, Tif
X-ray

More Images
Animation & Video
Tour of 47 Tucanae
animation

The Mysterious Afterlife of Stellar Giants
Click for high-resolution animation

More Animations
More Releases
47 Tucanae
47 Tucanae
(13 Mar 17)

47 Tucanae
47 Tucanae
(30 Jul 03)

47 Tucanae
47 Tucanae
(17 May 01)

Related Images
47 Tuc W
47 Tuc W
(19 Jul 05)

NGC 6266
NGC 6266
(30 Jul 03)


Related Information
Related Podcast
Top Rated Images
Data Sonification

30 Doradus B

Brightest Cluster Galaxies




FaceBookTwitterYouTubeFlickr