Strange design said:
So does that mean we have no real way of measuring these velocities when the galaxy is "face on?"
None that I know of. But then again, you don't get that many of those.
Strange design said:
I am intrigued by how these values infer dark matter
In two ways:
1) the velocities at large radii are high enough for the typical estimates of baryonic matter (gas+stars) to be insufficient to keep the galaxy bound. I.e., they exceed the escape velocity you'd calculate without extra mass.
2) the velocities are almost constant across most of the galaxy (except for the centre). Recalling Kepler's laws you'd expect that the farther away from centrally-concentrated mass, the lower the orbital velocity. A flat rotation curve is characteristic of a spherically-symmetric, continuous distribution of matter. For example, it's what you'd expect the rotation to be in a spherically symmetric cloud of gas - the farther you get from its centre, the more mass there is to attract you.
You get this sort of discrepancy:
In order to maintain such flat curve, you need a lot of extra matter. Its total mass must grow linearly with radius from the galactic centre, and extend quite a bit past luminous (stellar) regions - this is because the rotation curves of hydrogen clouds orbiting beyond the galactic fringes are also measurable, and these retain the characteristic constant orbital velocity. The total amount of extra mass exceeds the visible mass by a factor of 5, so you know that's a major problem.
Measurement error is out of the question - these curves are way too common, and error bars are low.
So, we've got a few options:
- the law of gravity changes at large distances (example attempts at modifying gravity include MOND and TeVeS), so that flat curves are produced
- there is more invisible baryonic matter distributed in galactic halos than we accounted for (e.g. a very large population black holes, dim stars, etc., collectively known as MACHOs - massive compact halo objects)
- there is some extra non-baryonic matter (such as neutrinos, or some other as of yet unknown type of particles, collectively known as WIMPs - weakly interacting massive particles)
Neither one of those is especially appealing from the aesthetic standpoint, but one needs to keep in mind that nature doesn't care what we do or don't find appealing.
Each possibility has its advantages and problems, but the last one is currently favoured, as there are additional observations that seem to be supporting WIMPs. These observations include the bullet cluster, and the anisotropies of the cosmic microwave background radiation.
The last word in this (dark) matter hasn't been said yet, though.
