Starship Asterisk*

flash wrote:It seems to me that the net angular momentum of a galaxy is highly correlated with its classification, "globular", "elliptical", "spriral"... in a globular (spherical) galaxy, since the inclination of the orbits of individual stars are random, the galaxy's net angular momentum must be (relatively) extremely small. As you proceed from globular to elliptical to spiral, the individual stars' orbital inclinations become less and less random, and so the galaxy's net angular momentum becomes larger. In spiral galaxies the orbit inclinations are nearly identical (at least outside of the central bulge?) and so the net angular momentum of such a galaxy is large.

My point here is that I don't see how a galaxy can evlove from one type to another without a significant change in angular momentum. Going from globular to elliptical to spiral... Where would this angular momemtum come from? How can this occur?

Ann wrote:Isn't it true that the bulge of any spiral galaxy could be regarded as a miniature elliptical galaxy? Isn't the bulge of our own galaxy pretty similar to a small elliptical galaxy? And aren't elliptical galaxies elliptical because the stars in them haven't settled into a plane of rotation, but instead they swarm around like bees?

Come to think of it, isn't that what globular clusters are like, too?

Check out this APOD from 2002, which shows a simulation of the motions of the stars inside a star cluster.

Ann

Charlie Patriot wrote:Many thanks for trying to square me away on the orbits of the stars. I still have a question however: If the nebula is orbiting on a plane affected by the gravitational pull of the black hole, I would assume the plane of it's orbit was established by this gravity. If so wouldn't the stars tend to align themselves on the same PLANE.? Just can't seem to get it through my thick head how the stars would orbit TOWARDS the gravitational pull, and then opposite AWAY from.??? Sorry if I'm bugging you. I really enjoy this site and have convinced many of my friends to enjoy it as well. THANKS.!! Charlie

zbvhs wrote:Where in that plethora of ellipses is the common focus that marks the location of the purported black hole?

Chris Peterson wrote:

soldier123 wrote:Galactic centre is a very busy place. Does anyone know how far from centre is habitable?

You can probably be quite close to the core and find things "habitable". But you might need to be outside the bulge completely to find stars where advanced life could form, since in the higher density center solar systems might be fairly unstable, meaning planets would not exist in their stars' habitable zones long enough to really give life a chance.

Ann wrote:Think of it like this. Is the Earth falling into the Sun? Clearly not.

Okay, now that the Sun had turned into a black hole, would the Earth fall into it? No, not at all. The Earth would continue orbiting the black hole in the same way it that it had orbited the Sun. There would be no difference. In fact, anything that is orbiting the Sun today without falling into it would continue orbiting it in the same way after it had turned into a black hole.

Is nothing falling into the Sun, then? Yes indeed, some comets are falling into the Sun.

zbvhs wrote:Here's what confused me about the illustration: The central body of an elliptical orbit is at one of the ellipse's foci. Except for three of the orbits shown, possibly a fourth, the foci appear to be all over the map.

Is this merely an indication of the accuracy of the orbit determinations for the individual stars? How were the observers able to obtain lateral positions or velocities in order to make the orbit determinations? Are the individual stars moving fast enough that changes in their positions would be apparent over, say, a few tens of years?

It occurs to me that a keen-eyed observer might be able to catch an actual indication of the presence of a central black hole (if one exists). One of the orbits is nearly edge-on. Some sort of lensing effect might be visible as the star in the orbit passes behind the black hole. If that event won't occur for another couple of hundred years, never mind, but still it might be something to watch for.

soldier123 wrote:When we see pictures of spiral galaxies, like the Milky way. It seems that in most every case, it is assumed there is a massive black hole in the centre. My impression of a spiral Galaxy is that the spiral is rotating like water going down a plug hole. If this is true. Does this mean that the black hole will eventually consume the entire Galaxy?

Ricky wrote:Maybe dumb question, but where is the black hole in this picture?

soldier123 wrote:When we see pictures of spiral galaxies, like the Milky way. It seems that in most every case, it is assumed there is a massive black hole in the centre. My impression of a spiral Galaxy is that the spiral is rotating like water going down a plug hole. If this is true. Does this mean that the black hole will eventually consume the entire Galaxy? :?

soldier123 wrote:Galactic centre is a very busy place. Does anyone know how far from centre is habitable?

Sam wrote:What kind of pictures can we expect to see? Will the action show up in radio and infrared?

nstahl wrote:Exactly. Surely in the case of a planetary system the glob of gas and dust that will become the star and planets, etc. starts with some net rotational momentum about an axis through the center of mass, which would define the plane the system ends in. But to start with, there'd be lots of stuff out of that plane orbiting around the center of mass from all directions and colliding with other parts causing, I'd imagine, some losing enough momentum it falls to the center and some being diverted over time into the plane the system ends up occupying. A sort of friction.

For an elliptical galaxy, that hasn't happened; I suppose because the gas and dust condensed into stars and such before it could cause enough "friction" on a galaxy-wide scale to reduce it to a plane.

At least that's my intuition.