Neutron stars
Neutron stars
It is predicted that supernovae triggered by stars that do not have enough mass for their cores to form black holes will result in neutron stars.
Neutron stars are small (about 20km across), rotate rapidly and are incredibly dense. They are mostly made of neutrons that formed as electrons combined with protons in the atomic nuclei of the dying stars' collapsing cores. Their powerful magnetic fields lead to radio pulses that can be detected on the Earth each time the stars rotate.
Image: An X-ray image of the neutron star inside the Crab Nebula and surrounding rings of particles (credit: NASA/CXC)
Watch and listen to clips from past programmes TV clips [8] Radio Programmes [1]
Howard Stableford of Tomorrow's World takes to a hot air balloon to explain how a star explodes in a supernova and leaves behind a neutron star or a black hole.
Neutron stars are the extremely dense remains of dead stars and are very powerful objects.
Jocelyn Bell Burnell's discovery of pulsars paved the way for the acceptance of black holes as a serious idea.
Professor Dame Jocelyn Bell Burnell explains what pulsars are and how they got their name.
Jocelyn Bell Burnell discovers pulsars
Kathy Sykes talks to Jocelyn Bell Burnell about her discovery.
As a student at Cambridge, Jocelyn Bell Burnell discovered pulsars using a radio telescope. Pulsars are rapidly rotating neutron stars whose regularly occurring energy pulses are detected by astronomers on the Earth.
About Neutron stars
A neutron star is a type of stellar remnant that can result from the gravitational collapse of a massive star during a Type II, Type Ib or Type Ic supernova event. Such stars are composed almost entirely of neutrons, which are subatomic particles without electrical charge and with slightly larger mass than protons. Neutron stars are very hot and are supported against further collapse by quantum degeneracy pressure due to the Pauli exclusion principle. This principle states that no two neutrons (or any other fermionic particles) can occupy the same place and quantum state simultaneously.
A typical neutron star has a mass between 1.35 and about 2.0 solar masses , with a corresponding radius of about 12 km if the Akmal–Pandharipande–Ravenhall equation of state (APR EOS) is used. In contrast, the Sun's radius is about 60,000 times that. Neutron stars have overall densities predicted by the APR EOS of 3.7×1017 to 5.9×1017 kg/m3 (2.6×1014 to 4.1×1014 times the density of the Sun), which compares with the approximate density of an atomic nucleus of 3×1017 kg/m3. The neutron star's density varies from below 1×109 kg/m3 in the crust, increasing with depth to above 6×1017 or 8×1017 kg/m3 deeper inside (denser than an atomic nucleus). This density is approximately equivalent to the mass of the entire human population compressed to the size of a sugar cube.
In general, compact stars of less than 1.38 solar masses – the Chandrasekhar limit – are white dwarfs, and above 2 to 3 solar masses (the Tolman–Oppenheimer–Volkoff limit), a quark star might be created; however, this is uncertain. Gravitational collapse will usually occur on any compact star between 10 and 25 solar masses and produce a black hole.
This entry is from Wikipedia, the user-contributed encyclopedia. If you find the content in the 'About' section factually incorrect, defamatory or highly offensive you can edit this article at Wikipedia.
Continue your journey
bbc.co.uk navigation
BBC links
© 2012
The BBC is not responsible for the content of external sites. Read more.
This page is best viewed in an up-to-date web browser with style sheets (CSS) enabled. While you will be able to view the content of this page in your current browser, you will not be able to get the full visual experience. Please consider upgrading your browser software or enabling style sheets (CSS) if you are able to do so.