That would be a white dwarf, which is the super dense remains of star that is no longer capable of fusing hydrogen. White Dwarfs continue to shine because they are very hot however, over time the star will lose most of its heat and become a black dwarf.
Massive stars do not cool as they collapse, the collapse in on themselves because their cores become too heavy and dense, these atoms in the core are in an area so dense and so hot that it continues to increase its temperature as it explodes.
A gas that cools and condenses can become either a liquid or a solid, depending on the pressure.
rises and cools
it goes down
the next stage of a white dwarf is the black dwarf which is form when the degenerate electron slowly cools down by thermal radiation but the time required for a white dwarf to become a black dwarf is bigger than the current age of universe so the evidence of a black dwarf isn't found yet
cools slowly.
Cools quickly, relative to intrusive igneous rock which cools slowly underground.
The object that cools more slowly would have the greater specific heat, because the amount of heat that is needed to raise the temperature of it one degree is less than the amount of heat needed to raise the temperature of the first object one degree. i.e. the object that cools quickly does so because it doesn't need a lot of heat to increase the temperature of it by one degree and the one that cools more slowly does so because it needs more heat to increase the temperature of it by one degree.
rock because when the lava or magma cools slowly it starts to harden.
bigger
when magma cools slowly it becomes extrusive igneous rock
crystal
alright, if it cools quickly it will form pumice because of the bubbles in it. if it cools slowly, it will form obsidian.
if lava cools slowly, it will have a lot of crystals. When it cools fast, there will be little to no crystals what s ever.
"Larger than if it cools quickly" is about all that's definitively possible to say.
Small, because it cools slowly
yes