ACLerok said:Okay, I am told to find the average density of a neutron star with the same mass of the sun but with a radius of only 20km. I figured this would be pretty simple so I just would divide the Sun's mass (found using Google) by the volume of the neutron star which would be (4/3)*pi*r^3 with r being 20000. But it's telling me this is incorrect. Can someone please tell me what's wrong?
The average density of a neutron star is approximately 10^17 kg/m^3, making it one of the densest objects in the universe. This means that even though a neutron star may have a mass similar to that of the Sun, it has a radius of only about 10 km.
The average density of a neutron star is calculated by dividing its mass by its volume. The mass of a neutron star is estimated based on observations of its effects on surrounding matter, while its volume is estimated based on its size and composition.
The high density of a neutron star is primarily caused by the immense gravitational force exerted by its mass. This causes the protons and electrons in the star to combine and form neutrons, resulting in a highly compact and dense object.
The average density of a neutron star is significantly higher than that of other celestial objects, including white dwarfs, black holes, and even the core of the Sun. It is only surpassed by quark stars, which have a theoretical density of 10^18 kg/m^3.
Yes, the average density of a neutron star can vary depending on its mass and composition. Higher mass neutron stars tend to have higher densities, and the presence of exotic matter such as strange quarks can also affect the overall density of a neutron star.