Yes, a nebula is far larger than a neutron star. A neutron star is a few miles across. A nebula is light years across.
No. A nebula is a billion, if not more, times larger than our Sun
No. A neutron star is quite small, generally only a few miles across. A nebula is light years across.
Yes. Stars form within a nebula.
Stars are much bigger than planets. The only stars that are smaller than planets are neutron stars.
No. A neutron star is many times denser than a white dwarf.
Yes, a solar nebula is much larger than a neutron star. In terms of objects in space, neutron stars are tiny; only a few miles across. A stellar nebula such as the one that formed the sun is light years across.
No, a neutron star can't become a nebula. A neutron star is not made of atomic matter, has less mass than a nebula, and has no mechanism by which to expand.
No. A neutron star is quite small, generally only a few miles across. A nebula is light years across.
A white dwarf is much larger than a neutron star.
No. A nebula is a billion, if not more, times larger than our Sun
Because the atoms inside the neutron star are squashed together to the point that they cannot move anymore, for example a teaspoon of neutron is about 90,000,000 tonnes. So basicly pretty much anything in the universe isn't as dense as that. hope this helps.
No. A neutron star is quite small, generally only a few miles across. A nebula is light years across.
A black hole has more mass than a neutron star, but if you are comparing volume it would depend on the mass of the black hole. A neutron star is estimated to be about 14 miles in diameter, which is larger than the event horizon of a black hole up to about 3.8 times the mass of the sun. A more massive black hole will be larger.
Yes far bigger. A red giant would cover the distance from the Sun to the Earth. A neutron star could be the size of New York City.
Yes. Stars form within a nebula.
The helix nebula is more close than the ring nebula, as well as much brighter and larger than the ring but with low surface brightness.
It can become a white dwarf, a neutron star or a black hole, depending on the mass that remains at the end of the star's life.