No. Stars become white dwarfs after dying.
When a star dies, it can leave behind different types of stellar remnants depending on its mass. Some examples include white dwarfs, neutron stars, and black holes. White dwarfs are formed from the remnants of low to medium mass stars, neutron stars are formed from the remnants of massive stars, and black holes are formed from the remnants of the most massive stars.
Depending on their initial mass, stars can become white dwarfs, neutron stars, or black holes after they die. The type of remnant left behind is determined by the mass of the star and the processes that occur during its death.
There are three types of stellar remnants. Low to medium mass stars will become white dwarfs. High mass stars will become neutron stars. Very high mass stars will become black holes.
white dwarf ---> black dwarf. Only difference is amount of heat.Neutron star (also knows as Pulsar)black holesub-stellar wreckage. Veil Nebula, Planetary nebula,1. Dwarf stars2. Supernovas (Neutron Stars)3. Black holesIt depends on the size and mass
A nebula does not directly turn into a white dwarf. A nebula will collapse to form stars. Low to medium mass stars become white dwarfs after they die. Some are the result of a supernova and do not collapse, they merely dissipate over time. The Crab Nebula is the most prominent example of this.
Stars that become white dwarfs die but become black holes . Neutron stars are born from a Super Nova that stored its energy and became a neutron star.
No. Blue stars will generally leave behind neutron stars or black holes.
Red dwarf stars have such long lifetimes that none of them ever have yet. Presumably, they will eventually go through the white dwarf phase before cooling entirely and becoming "black dwarfs".
When a star dies, it can leave behind different types of stellar remnants depending on its mass. Some examples include white dwarfs, neutron stars, and black holes. White dwarfs are formed from the remnants of low to medium mass stars, neutron stars are formed from the remnants of massive stars, and black holes are formed from the remnants of the most massive stars.
Depending on their initial mass, stars can become white dwarfs, neutron stars, or black holes after they die. The type of remnant left behind is determined by the mass of the star and the processes that occur during its death.
There are three types of stellar remnants. Low to medium mass stars will become white dwarfs. High mass stars will become neutron stars. Very high mass stars will become black holes.
Stars can die in many ways. After a long life, there are two distinct paths to a star's death. They can either start the path to death after becoming a planetary nebula, or a red supergiant. Following the red giant phase some stars become white dwarfs and then black dwarfs. If the star is a red supergiant, it supernovas, then it will either become a black hole, or a neutron star. Those are the only known and recorded ways that stars can "die". However, the science behind the death is much more complicated and intriguing. Source: Wikipedia
Percentage wise. Most stars do not explode. Only about 1 in 3 million will explode as a supernova. The rest, like our Sun will just die quietly and become white dwarfs.
white dwarf ---> black dwarf. Only difference is amount of heat.Neutron star (also knows as Pulsar)black holesub-stellar wreckage. Veil Nebula, Planetary nebula,1. Dwarf stars2. Supernovas (Neutron Stars)3. Black holesIt depends on the size and mass
A nebula does not directly turn into a white dwarf. A nebula will collapse to form stars. Low to medium mass stars become white dwarfs after they die. Some are the result of a supernova and do not collapse, they merely dissipate over time. The Crab Nebula is the most prominent example of this.
There are all kinds of stars in our Milky Way galaxy. Our sun is a G2V type star. There are red giants, blue giants, white dwarfs, red dwarfs, brown dwarfs, and probably even black dwarfs (burned out suns), neutron stars, and pulsars. There are also herbig-haro objects, a peculiar type of star that emits collimated bipolar jets of radiation.
Exactly what happens depends on the mass of the star. Low mass stars first expand into giants, then shrink to white dwarfs. Stars with a little more mass than the Sun end up as neutron stars; stars with considerably more mass with the sun end up as black holes.