Matterwave said:This is part of the rotation curve problem in Astrophysics. The rotation curve of galaxies do not drop off as expected by applying known laws of gravity on the observable matter. Thus, there is hypothesis of "dark matter halos" that exist all around galaxies. This extra matter (which extends quite far out) can flatten out rotation curves to significant distances from the center of the galaxy.
Matterwave said:Oh, well, that's because velocity only goes down as the square root of r at large distances (outside where luminous matter appear).
Out at very large distances, one could approximate the galaxy as a point source of gravity. In that case, for circular orbits:
[tex]v=\sqrt{\frac{GM}{r}}[/tex]
As r goes up, v goes down, but only as a square root. This function is asymptotic to 0 as r goes to infinity, but is very slowly doing so. At distances that the graph has, the function doesn't approach zero quickly.
The asymptote of expected rotation curve velocities refers to the predicted maximum velocity that a star or gas cloud should have as it orbits around the center of a galaxy.
The asymptote of expected rotation curve velocities is important because it helps us understand the distribution and amount of mass within a galaxy. It can also provide insights into the nature of dark matter and the overall structure of galaxies.
The asymptote of expected rotation curve velocities is calculated by using Newton's Law of Gravitation to determine the expected force of gravity between a star or gas cloud and the center of a galaxy. This force can then be used to calculate the expected orbital velocity.
The asymptote of expected rotation curve velocities can be affected by a variety of factors, including the distribution and amount of visible matter within a galaxy, the presence of dark matter, and the overall shape and structure of the galaxy.
In many cases, the actual observed velocities of stars and gas clouds within a galaxy do not match the predicted asymptote of expected rotation curve velocities. This discrepancy has led to the development of theories such as dark matter to explain the missing mass and explain the observed velocities.