It varies, but it is several tons per cubic centimeter - i.e., millions of times as dense as water.
A white dwarf is much denser than the Sun. White dwarfs have a typical density around 1 million times greater than the density of the Sun, resulting in a mass similar to the Sun's but packed into a much smaller volume.
To calculate the density of the white dwarf, we first need to determine its volume using the volume of the Earth. The volume of the Earth is about 1 trillion cubic kilometers. If we assume the white dwarf is roughly the same size as the Earth, its density would be the mass (1.3 Msun) divided by the volume of the Earth. This calculation would yield a rough estimate of the white dwarf's density.
The density of a white dwarf is much greater than that of material on Earth. White dwarfs are incredibly dense objects that result from the collapse of a star's core, leading to a mass comparable to the Sun but compressed into a volume roughly the size of the Earth.
The obvious reason is that the specific star has bigger density compared with the Sun. For example, that star could be a "white dwarf star". A white dwarf mostly contains "electron degenerate matter", which is very dense. A white dwarf is a small dense star.
A white dwarf.A white dwarf.A white dwarf.A white dwarf.
A white dwarf is much denser than the Sun. White dwarfs have a typical density around 1 million times greater than the density of the Sun, resulting in a mass similar to the Sun's but packed into a much smaller volume.
To calculate the density of the white dwarf, we first need to determine its volume using the volume of the Earth. The volume of the Earth is about 1 trillion cubic kilometers. If we assume the white dwarf is roughly the same size as the Earth, its density would be the mass (1.3 Msun) divided by the volume of the Earth. This calculation would yield a rough estimate of the white dwarf's density.
No, the density of a neutron star is much higher than that of a white dwarf. Neutron stars are composed mostly of densely packed neutrons, while white dwarfs are made of electron-degenerate matter. Neutron stars are some of the densest objects in the universe.
The density of a pulsar or neutron star is much greater than that of a white dwarf. A typical (if there is such a thing) neutron star has a density of between 8.4 × 1016 to 1 × 1018 kg/m3 whereas a white dwarf has a density of about 1 × 109 kg/m3
See related questions
A white dwarf is a white hot solid ball of nickel-iron alloy, a black hole is an infinitesimal singularity of infinite density surrounded by total emptiness.
A red giant has been greatly inflated by the energy from nuclear fusion in a shell around the core. In a white dwarf fusion has stopped, the core has collapsed, and the low-density outer layers have been expelled into space.
The density of a white dwarf is much greater than that of material on Earth. White dwarfs are incredibly dense objects that result from the collapse of a star's core, leading to a mass comparable to the Sun but compressed into a volume roughly the size of the Earth.
At that stage, it will no longer produce energy. All the energy it radiates out is its residual heat, and it will gradually get colder and colder. Due to its small size and high density, however, it will take trillions of years for the white dwarf to become a black dwarf.
The obvious reason is that the specific star has bigger density compared with the Sun. For example, that star could be a "white dwarf star". A white dwarf mostly contains "electron degenerate matter", which is very dense. A white dwarf is a small dense star.
At that stage, it will no longer produce energy. All the energy it radiates out is its residual heat, and it will gradually get colder and colder. Due to its small size and high density, however, it will take trillions of years for the white dwarf to become a black dwarf.
A white dwarf.A white dwarf.A white dwarf.A white dwarf.