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47 Tucanae Animations
Click for low-resolution animation
Tour of 47 Tucanae
Quicktime MPEG
Neutron stars are the ultra-dense cores that are often left behind after massive stars run out of fuel and collapse. In fact, these compact objects, which are less than 10 miles in diameter, contain the densest matter known in the Universe outside of a black hole. New results from Chandra and other X-ray telescopes are giving scientists information about important properties of neutron stars. By studying eight neutron stars, a group of researchers have come up with the one of the most reliable determinations yet of the relation between the radius of a neutron star and its mass. They looked at the neutron stars in double, or binary, systems where they are in orbit with stars like our Sun. One of these systems is known as X7 and is found in the globular cluster 47 Tucanae. 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.
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(Credit: NASA/CXC/A. Hobart)



Click for low-resolution animation
The Mysterious Afterlife of Stellar Giants
Quicktime MPEG
Neutron stars are the ultra-dense cores left behind after a massive star reaches the end of its life and explodes. The star's outer layers are blasted away in the explosion, but material at the centre of the star collapses in on itself. This forming a tightly packed ball of material and what we end up with is the densest (meaning 'most tightly packed') object known in the entire Universe outside of a black hole: a neutron star!

This new space picture shows a group of stars called a globular cluster. These are some of the oldest objects in space - almost as old as the Universe itself! This means many of the stars within have already lived their lives. The most massive have long since exploded, leaving behind several neutron stars.

Using a neutron star within this cluster, along with several others, astronomers have worked out the relationship between the stars' mass (how much material they have) and how big they are.

The new data shows that an average neutron star, with the same mass as around one and a half of our Sun's, would be around 12 km across. That's about the size of a town! With all this material packed down into such a small space, neutron stars are unbelievably dense objects. The pressure at their centers is over ten trillion trillion times the pressure required to form diamonds inside the Earth.
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(Credit: NASA/CXC/April Jubett)


Return to 47 Tucanae (March 6, 2013)