narrator said:Thanks Chronos.. followup questions.. and these may seem silly but I'll ask anyway. Everywhere we look in the night sky there are stars. Do all the stars we see only belong to the Milky Way galaxy? Are there stars that are not attached to galaxies, off on their own in the space between galaxies?
Its a good question narrator.narrator said:Thanks Chronos.. followup questions.. and these may seem silly but I'll ask anyway. Everywhere we look in the night sky there are stars. Do all the stars we see only belong to the Milky Way galaxy? Are there stars that are not attached to galaxies, off on their own in the space between galaxies?
zhermes said:As Cosmo Novice said, we can see some galaxies with the naked eye, and more with telescopes---we can almost-never distinguish individual stars however.
As a historical aside: its interesting to note that only in the last 100 years did astronomers realize there were other galaxies at all. Until then, it was believed that our galaxy was the entire universe. The 'nebulae' (which are now known to be other galaxies) were simply anomalous objects at comparable distances to the stars.narrator said:It's an odd thing for us novices - we look up into the night sky and think we're seeing the universe, when in fact we're seeing almost exclusively only a part of our own galaxy.
Direction is not a clear variable in star density. However, there are severe disparities between some huge intergalactic voids, and the densities found in the galaxies that populate filaments and clusters, so direction AND density are correlated in that sense (mapping). It would be challenging to cosmology if we could show that direction of observation had any effect on the apparent stellar density that we observe.narrator said:Hi,
Is there a fairly even star (or galaxy) density in every direction we look, ignoring our own galaxy? Or are there some directions where our OU seem denser than others?
turbo-1 said:Direction is not a clear variable in star density. However, there are severe disparities between some huge intergalactic voids, and the densities found in the galaxies that populate filaments and clusters, so direction AND density are correlated in that sense (mapping). It would be challenging to cosmology if we could show that direction of observation had any effect on the apparent stellar density that we observe.
Star density outside our galaxy refers to the number of stars per unit volume in space beyond our own Milky Way galaxy. It is a measure of how many stars are present in a particular region of space.
Star density is typically measured using telescopes and other astronomical instruments. Scientists can use these tools to observe and count the number of stars in a particular region of space, and then calculate the star density by dividing the total number of stars by the volume of space.
The average star density outside our galaxy can vary greatly depending on the location and type of galaxy being observed. In general, scientists estimate that the average star density in our local group of galaxies is about 0.004 stars per cubic light year.
The density of stars outside our galaxy is generally much lower than within our own Milky Way. This is because our galaxy contains a large number of stars, while other galaxies can vary greatly in size and number of stars.
Studying star density outside our galaxy can help scientists better understand the formation and evolution of galaxies, as well as the distribution of matter in the universe. It can also provide insights into the overall structure and dynamics of the universe.