Oops! Can't blame you for that long URL in the post, by Peter Nielsen, which started this thread. It links to a Google Groups discussion of a rather interesting and scholarly paper, by C. Johnson, about stellar motions that deviate from simply drifting uniformly around the galactic core. I must confess, I haven't read all of it. [|)]
There are computer models which, with the help of a supercomputer, display collisions between galaxies in 3D, simulating billions of years in a few minutes. Two simple oval galaxies collide and the result is spiral-arm galaxies. I saw that on TV several years ago; it might have been Nova, on PBS. I wonder if C. Johnson got his idea from watching such a simulation.
Johnson speaks of "oscillations in both directions", which some posters have found to be unclear. I think he might mean both radial and axial directions, relative to the galaxy. In otherwords, stars near the center of the spiral arm simply follow an oval path around the galaxy, while a star near the outer limits of a spiral arm follows a flattened spiral around that longer oval path.
It's not easy to draw such a complex picture in words, but I'll try:
Start with a long cylindrical solid, full of stars, rotating about its longitudinal axis. The stars near the outer surface of the cylinder move rapidly, while those near the axis are nearly stationary.
Now, taper the ends of the cylinder, more or less to a point. Place two or more copies of that object so they radiate perpendicular to a central axis. Then twist the whole arrangement about that central axis so the objects spiral outward, with their original cylindrical axes in a plane. Finally, flatten the whole thing in that plane; i.e., flatten it parallel to the axis about which it is twisted.
So the motion of a star near the outer edge of the original cylinder will follow a flattened oval path relative to its "arm of the galaxy", while the center of that oval follows a much longer oval path around the core of the galaxy. The path of such a star around the galaxy would then be a flattened spiral, following a long oval.
Here's another way to describe the path of an individual star: Wrap a wire around a pipe to form a coil; remove the pipe and stretch the coil around a large circle, connecting the ends of the wire to each other. Then flatten the whole thing.
I'm not sure if that's what C. Johnson had in mind, but it works for me. The question is, does this obey the laws of physics. Only a supercomputer model can say for sure.
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This led into a discussion of whether such a galactic model makes it more or less likely for interstellar comets to be captured by our solar system. For that to happen, the comet would have to start with little more than the threshold energy (or velocity) for escape.
Now it seems to me that most of the stars in our arm of the galaxy ought to be moving according to the same general scheme, as described above. If so, I would expect our closest-neighbor stars and interstellar comets to have not-so-great velocities relative to one another. Alternatively, there is the traditional view of all the stars following more or less parallel oval paths around the galaxy, which suggests even less relative velocity for close neighbors. If, on the other hand, it's every star for himself or herself (like a busy street in Mexico), then our telescopes should be spinning in an effort to follow them. [V]
I don't think we can answer this question with Keppler's laws and a slide rule. We'll have to hand this problem over the supercomputers and many-body models, and trust their results. [^]
] for helping to drag this thread farther astray from the original topic. That's what I get for jumping in without first following your link to the
C. Johnson article
. [
)] I'll need some time to digest it before commenting.
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