Starship Asterisk*

dougettinger wrote:To use your term - everything in the known universe "evaporates" over tens of billions of years.

BMAONE23 wrote:I've never heard of one of these breaking up (though anything is poossible).

The simulation
This visualization presents a globular cluster composed of 6,144 stars. The width of the frame represents more than a hundred trillion miles. As the movie unfolds, the evolution of the cluster is shown in this time-lapse movie, in which each second represents thousands of years passing by! As the stars orbit one other, several stars are ejected from the cluster through close gravitational encounters with more massive stars. The stars are shown in a scientific approximation of what the human eye would see: each star's brightness depends both on its intrinsic brightness and on its distance away from the virtual camera, while each star's color is only slightly exaggerated.

The simulation
This visualization presents a globular cluster composed of 6,144 stars. The width of the frame represents more than a hundred trillion miles. As the movie unfolds, the evolution of the cluster is shown in this time-lapse movie, in which each second represents thousands of years passing by! As the stars orbit one other, several stars are ejected from the cluster through close gravitational encounters with more massive stars. The stars are shown in a scientific approximation of what the human eye would see: each star's brightness depends both on its intrinsic brightness and on its distance away from the “virtual camera,” while each star's color is only slightly exaggerated

rstevenson wrote:None of the above. They are orbiting their mutual center of mass.

tesla wrote:... Are the stars moving towards the center or moving outwards? If they are moving outwards, it is not gravity. If they are in a static position, it is not gravity. If they are moving inwards I guess it is a mythical black hole!

dougettinger wrote:Chris, thanks for answering my question and correcting me about Population I and Population II stars. Is it correct to assume then that most subsequent generation stars, young massive short-lived blue stars, and Population I stars with high metal content are mostly made in spiral and barred galaxies and irregular galaxies like the LMC? Older, possibly original stars, are mostly found in elliptical galaxies and the bulges/globular clusters of spiral galaxies.

Chris Peterson wrote:

dougettinger wrote:Then, I presume the stars in galaxial globular star clusters are consistently very old stars with very little higher metals. I believe astronomers call them Population I stars. I would also presume that these stars are all mid-size or smaller stars that would have long lives that compare with the age of the universe less 1 or 2 billion years. Are these presumptions proven by observational data?

Population I stars are high metal content, like the Sun. Globular clusters are made up of low metal, Population II stars, like those found in the galactic halo and bulge. The stars all appear to have formed at the same time, but they don't all have the same mass, so you find a range of luminosities. The stars in globulars are very old, as you suggest. Most seem to be about a billion years younger than the Universe- the same as galaxies. This is all well supported by observation. There are a small number of globulars that have different characteristics, such as split star populations. These aren't well understood, but might be the product of later evolution due to collisions or tidal effects.

dougettinger wrote:Are the globular clusters and their stars that are a halo around the Milky Way possibly as old as the age of the universe?

dougettinger wrote:Thanks for sharing that information that stars can form in various ways. I have not heard that explanation before but suspected that was the case.

Then, I presume the stars in galaxial globular star clusters are consistently very old stars with very little higher metals. I believe astronomers call them Population I stars. I would also presume that these stars are all mid-size or smaller stars that would have long lives that compare with the age of the universe less 1 or 2 billion years. Are these presumptions proven by observational data?

dougettinger wrote:Then, I presume the stars in galaxial globular star clusters are consistently very old stars with very little higher metals. I believe astronomers call them Population I stars. I would also presume that these stars are all mid-size or smaller stars that would have long lives that compare with the age of the universe less 1 or 2 billion years. Are these presumptions proven by observational data?

dougettinger wrote:How does the nebula hypothesis work for a star field that is 100 stars per ly^3 or even 8 stars per ly^3? Does not the nebula hypothesis require a very high volume interstellar molecular cloud (IMC)?

Chris Peterson wrote:

htom wrote:An average of 0.13 cubic light year per star? Eight stars per cubic light year? Did I make a mistake? What's the density as we approach the center? Presumably they would rotate a common center of mass ... but that wouldn't yield a globe. Are they being attracted to (repelled from!) a center?

Central densities in globulars are very high- 100 stars per cubic light year, or more. While the cluster has a center of mass, it really just forms a sort of "average" locus that the member stars orbit. In practice, "orbit" is a much more complex idea. The stars in a globular cluster are perturbed by other stars (and at the edges, by the parent galaxy). So stellar paths loop and twist. Since most stars are binaries, interactions can result in energy being added or removed from the binary systems, and transferred between different star systems. This results in a sort of mass sorting, where more massive stars tend to settle towards the core. It's a very complex system- one that can only be studied closely using computer models. And even then, the complexity of the system requires making certain assumptions and simplifications.

jando35 wrote:It seems eminently possible for someone with appropriate computer software to simulate the impression of the night sky from the centre of a globular cluster. Anyone have access to such?

Amir wrote:

BMAONE23 wrote:Is the Bubble feature in the bottom left corner an artifact of processing or part of a nebula?

anyone knows the answer?
seems to me all of the stars have the same bubble around them, but the one you mentioned is larger because the star has greater brightness.
so maybe we should blame filters, if there were any.

BMAONE23 wrote:Is the Bubble feature in the bottom left corner an artifact of processing or part of a nebula?

DonAVP wrote:

workgazer wrote:what would life / the view be like living on a planet in that cluster?

In the writeup regarding this image was a link from the word 'Packed'. The link takes you to an earlier APOD post showing what it might look like.
http://antwrp.gsfc.nasa.gov/apod/ap080906.html

Utah gazer wrote:0.01 cyl per star equates to interstellar distance of about 0.25 light years. But that's only an average. At the short end of that distribution, couldn't we talking about instellar distances of 0.1 ly or less?!? How close can one star be to another?

htom wrote:Planets in such a place may not have anything like an orbit at all.