Unruly Milky Way 23
empaler writes "Space.com is running a story about the movement history of the local group near our solar system. The belief until now has been that after an initial period of chaos in our galaxy, it had since 'been rather calm'. 'But this turns out not to be true. Stars have been perturbed all the time throughout the Milky Way history.'"
Mmm... (Score:1, Funny)
Plotting Ahead? (Score:4, Interesting)
ok, yeah, one can always hope
Re:Plotting Ahead? (Score:5, Informative)
Re:Plotting Ahead? (Score:1, Interesting)
Stars do collide - I'm sure quite frequently given the number of them. It's just a question of how likely it is to happen to any one particular star - ie: ours.
Re:Plotting Ahead? (Score:4, Insightful)
If the universe were nice and tidy, even the impressive accelerations seen there would be quite predictable. But complicating matters are the realities of *open systems* such as binary - or other multiple star - systems that *shed* mass from one star to a companion, or instabilities that may result in a star assuming a new size or perhaps *blowing up*.
One wonders where the initial assumption came from: the belief until now has been that after an initial period of chaos in our galaxy, it had since 'been rather calm'.
It seems it's just a slightly modified version of the geocentric view of the universe, in the sense that *that* view was hard to shake because it threatened not only the religious views but the general sensibilities of many people. If it *looked* like things moved around the Earth - so the story goes - Interestingly, it was the observations of those willing to travel a bit, whether Eratosthenes measuring the Earth or countless mariners - along with some good logic - that built a *database* that would allow others to get a handle on cosmic movement to a greater extent.
When we have looked out through the big domes over the last 90 years or so and seen these *violent* things - supernovae, etc - occurring in distant places - because we are capable of seeing so many *times* at once - It must have seemed like our part of the universe was pretty quiet.
But in this case it was taking the time to not rush to judgement (or to disprove an assumption that had been rushed) in that these astronomers "spent 15 years making 1001 nights of observations to detail the motions of more than 14,000 stars that are currently in the solar neighborhood"
That's a lot of time and a lot of stars for a research paper that will added to the file as 'done that'.
Re:Plotting Ahead? (Score:5, Insightful)
Stars do collide - I'm sure quite frequently given the number of them. It's just a question of how likely it is to happen to any one particular star - ie: ours.
Sorry, but stars collide quite rarely, because they are so astonishingly small compared to the space around them. Even in galactic clusters -- as dense as space gets when one is looking at stars -- stars rarely physically collide.
Now, star SYSTEMS collide. That means that in a galactic cluster, two solar systems can pass closely enough to cause orbital disruption. This would be especially a risk to life, as any disruption of a star's Oort cloud would cause an incoming rain of cometary objects.
But that being said, the frequency of stars physically colliding is unimaginably small.
Even when galaxies collide, it's a gravitational "collision" and not a collision like a car hitting a wall. When galaxies collide, there are no stellar collisions. Yes, people get a hole-in-one in a golf course. But to go to the original example, if the tee was ten miles from the cup, how often would that happen? Keep in mind that stars are not aimed. :)
About the only way for stars to collide would be gravitational capture with something causing the orbit to lose energy. With that, one star would spiral into another (or more reasonably the two stars would spiral toward each other).
Supermassive black holes do not require stars collding into them. The huge quantities of dust and gas in the center of a galaxy are sufficient. And easier to capture.
How common is orbital disruption? (Score:2)
I've wondered about this.
What percentage of solar systems in the spriral arms would have experienced a larger disruption than a bunch of measly dinosaur killers?
Any life on a planet in such a system would at least be "reset" quite a bit
Re:How common is orbital disruption? (Score:2)
Re:Plotting Ahead? (Score:2)
Re:Plotting Ahead? (Score:3, Informative)
Rather than just asserting that blindly, why don't we work out the numbers?
The only place in the Milky Way that stars collide are inside globular clusters, where they form "blue stragglers". There are about 3000 known blue stragglers in the Milky Way (Piotto et al. 2004). The rate is probably higher now than in the past (it should increase with time as more clusters undergo core collapse), but averaging over the 13.7 billion year hist
Re:Plotting Ahead? (Score:5, Informative)
Very true! Two things though:
Plotting ahead is useful because even though stars don't collide, they do come close enough to each other to disrupt planetary systems. Even just preturbing the Oort cloud a bit would cause destructive impacts on earth that could wipe out all life.
Second of all, galaxies "collide" however it's kinda like two clouds of smoke "colliding" because there's really not much actual physical contact (although black holes might eat quite a bit during this period).
Good to point this out though! Galactic dynamics is quite fascinating, and much more complex than you'd expect!
Cheers,
Justin
Re:Plotting Ahead? (Score:5, Informative)
The can figure out where things are going about as well as they can figure out where things came from. It depends critically on our knowledge of where everything else is that the stars can gravitationally interact with. It can be highly chaotic when stars pass at all close to one another. (Using the appropriate definition of "close," which does not include any likelyhood of collision.) If there's a dense gas cloud we're not aware of in the wrong spot, that would invalidate much of this kind of simulation forward or backward.
Local stars are all moving slowly enough (relative to us) that there are no surprises likely. The only kind of surprises we could get would be a brown dwarf or the like, something not visible until it's close. In terms of human lifetimes, this isn't changing very rapidly at all.
Remember, the animation from the article covers 250 million years! Two such rotations ago, there was no life on land and fish were only just beginning to appear. One rotation ago -- the beginning of the simulation -- was the time of the Permian mass extinction. That was a freaking long time ago! That predates roaches! And mammals.
If we're lucky, we'll still be around in another 250 million years.
Re:Plotting Ahead? (Score:1)
Actually roaches and mamals already existed back then. Expecially roaches I bet existed in large numbers
Sorry, but roaches and mammals are both younger than 250 million years. Not by a whole lot, but still, younger is younger. And like I said, two orbits ago there was no life on land. Probably not even algae on rocks. Only oceanic life.
In comparison to the 4.5 billion years age of the Earth, multicellular life is very young.
To bring it back on topic, and talking about choatic orbits, we are so f
Extrapolations (Score:2, Interesting)
They imply they are measuring the change in both relative position and brightness of the stars. From their conclusion and simulation showing that stars appear closer now (than from 15 years ago), I guess this means the change in relative brightness was the
Re:Extrapolations (Score:2)
That's definitely true... and if you asked what the error in the trajectory of any individual star is, you'd find it's pretty high. But the aggregate distribution should be pretty well constrained... you know what fraction are moving outwards, what fraction a
Re:Extrapolations (Score:1)
I also can see now that the conclusions do not imply that our neighboring stars are all moving towards us - but instead they are moving so fast that they must have been very far away a long time ago.
Re:Plotting Ahead? (Score:3, Informative)
The problem, though, is that getting good enough kinematical information to do this is hard for stars that aren't near the Sun. You notice that all of the stars end up right near the Sun - that's not a coincidence! Those are the ones whose orbits we can get a handle on precisely because right now they're close enough that it's easy to get their kinematics.
You can imagine that if you waited 220
Now that's some history ! (Score:2, Redundant)
Humph! (Score:1)