Starship Asterisk*

garry wrote:If other forms of galaxy structures all have a black hole, rotate & are effected by gravity, and a globular galaxy is supposed to have a black hole, does not rotate and is effected by gravity, why the difference? Are the stars moving in towards the centre or moving away? One can speculate as to why, but it would be nice for someone to say sometime we don't now!

Ailean4321 wrote:Amazing, you have fulfilled two of my future aspirations:
Astronomer/physicist & Colorado.
Although, I don't know that my brain is cut out for the former.

Should be called "Queen Anne's Lace" cluster.

NoelC wrote:For the visually-oriented among us, some fun links. I couldn't find any done really, really well in HD though... Sounds like it could be a fun simulation project for someone.
-Noel

Ailean4321 wrote:Dear Chris & Cabellasus,
What are your occupations? I'm curious. & Intrigued.

Harry SevenEagles wrote:Fantastical !

prettttyyyy

cabellasus wrote: Ah, so I'm not crazy. There "is no compelling theory describing how globular clusters form" ???

Mentally, certainly, i cannot picture how globular clusters OR spherical galaxies form, if they form by accretion (and not capture, which g.c.'s certainly do not, given relative uniformity of star types/ages). Picture a sphere of randomly moving particles. How would they accrete?

One must admit, that if a planetary system was spherical, without an ecliptic plane , and whose planets had random orbits, then astronomers would argue it formed by capture, not accretion. Right?

It is difficult to seriously consider this in the absence of any compelling theory describing how globular clusters formed. My own view is that disc-like rotating systems are a special case, and occur when a rotating system forms under viscous conditions that favor a single axis for angular momentum. But in lower density systems, there is no reason to expect disc formation, and in the long term I expect disc-like systems to evolve to elliptical and ultimately spherical systems. Globular clusters are currently in high entropy states, and I see no mechanism to lower that entropy and produce a more ordered or symmetrical structure.

cabellasus wrote:But, nonetheless, IF a planet lost all of its angular momentum, it would move and accelerate towards the sun, no question.

All I'm wondering is, that there must be so much mass near the center of these clusters, that the stars must have to have tremendous angular momentums (and therefore velocities) and that these individual orbits would eventually disclose a majority axis of symmetry. How can they all have formed at about the same time, and yet have individual planes of orbit as you say, and these be so random as to betray no majority pole/disc ??????????

Ann wrote:

atalas wrote:Is that a blue planetary to the left of center?

I guess it could be. Here is another Hubble image of M15, which shows a hydrogen-rich pink planetary nebula in M15:
Note the pink planetary at the upper left. The blue object in today's APOD could be the same planetary, if a hydrogen alpha filter was not used to produce today's APOD.

Chris Peterson wrote:

Ailean4321 wrote:Absolutely beautiful.
I wish I could see it with my own two eyes.

Why can't you? It is large and bright- visible with the naked eye, remarkable through binoculars, and stunning with a small telescope, which will show it to your eye looking almost identical to this HST image.

casabellasus wrote:Chris - thanks. i know it's not rigid. But neither is a galaxy, and yet a galaxy rotates.

solar systems rotate, and if the planets didn't, they would crash into the sun, as would the ISS around earth.

I know there must be relative motion between the clusters stars. But IF they rotated/orbited the cluster's center fast enough to count (centrifugal-wise), then they would have a discernable axis, instead of such perfect radial symmetry.

Chris Peterson wrote:A globular cluster isn't a rigid body- there is really nothing like an object that could rotate. It is a collection of millions of stars, each in its own orbit. And it is those individual orbits that maintain the global stability of a globular. If you could look at this thing sped up to thousands of years a second, it would look like a swarm of bees- the stars are not fixed in position with respect to each other.

cabellasus wrote:But I still can't fathom, with a massive black hole in the center, and the density of stars centrally, how the thing doesn't gravitationally collapse quickly (it's ancient, apparently) without any rotational "centrifugal" force. And if it were rotating substantially (enough to help prevent collapse) then it would have polar symmetry, instead of radial/spherical.

Ailean4321 wrote:Absolutely beautiful.
I wish I could see it with my own two eyes.