by alter-ego » Mon Mar 31, 2014 1:39 am
Nitpicker wrote:
Thanks Chris. The "physical plane that separates the galaxy's northern and southern hemispheres" does not appear to be well defined, other than as a self referential definition. Or perhaps I have misunderstood. Is there a basis for defining it? I agree there is no confusion in alter-ego's statement, but there is often confusion. Perhaps it should be stated as the "natural galactic plane", versus the "fundamental plane of the galactic coordinate system" (which is quite a mouthful). There is not a huge difference between the two planes (less than a quarter of a degree if we are 100ly from the natural plane and 25,000ly from the core). Another term which is easily confused is "galactic poles". The polar axis of the Milky Way, projecting from the core, normal to the natural plane, appears as a line or arc in the sky to us. But there are also the poles of the galactic coordinate system, which appear as points in the sky to us. The line joining these points is normal to the "fundamental plane of the galactic coordinate system" and passes through the Sun (and us within a sensible tolerance). Quite a difference.
The solar system has an analogous definition which conceptually is the same, but maybe not estimated the same way. The solar system's "natural plane" is referred to the
Invariable Plane. In this reference system, the ecliptic is off by 1.57°. However, determining the galaxy's "invariable plane" and it's precision depends on the estimations and assumptions. It seems a lot more difficult to determine it, e.g it appears to be defined based on visible matter and not dark matter (?). Also, defining the solar system's invariable plane and barycenter seems at least tenable based on it's relatively near-zero finite size compared to the galaxy.
Wikipedia wrote:
... The invariable plane of a planetary system, also called Laplace's invariable plane, is the plane passing through its barycenter (center of mass) perpendicular to its angular momentum vector. In the Solar System, about 98% of this effect is contributed by the orbital angular momenta of the four jovian planets (Jupiter, Saturn, Uranus, and Neptune). The invariable plane is within 0.5° of the orbital plane of Jupiter,[1] and may be regarded as the weighted average of all planetary orbital and rotational planes.
In the picture below, the galactic equator (as we are used to thinking of it) is equivalent to the Earth's ecliptic which passes through the Sun's center. The "Galactic Plane" is what I conceptually associate to the Invariable Plane. Other than looking at snapshot of observable mass distribution, I don't know how it is exactly determined.
[quote="Nitpicker"]
Thanks Chris. The "physical plane that separates the galaxy's northern and southern hemispheres" does not appear to be well defined, other than as a self referential definition. Or perhaps I have misunderstood.[color=#0000FF] Is there a basis for defining it?[/color] I agree there is no confusion in alter-ego's statement, but there is often confusion. Perhaps it should be stated as the "natural galactic plane", versus the "fundamental plane of the galactic coordinate system" (which is quite a mouthful). There is not a huge difference between the two planes (less than a quarter of a degree if we are 100ly from the natural plane and 25,000ly from the core). Another term which is easily confused is "galactic poles". The polar axis of the Milky Way, projecting from the core, normal to the natural plane, appears as a line or arc in the sky to us. But there are also the poles of the galactic coordinate system, which appear as points in the sky to us. The line joining these points is normal to the "fundamental plane of the galactic coordinate system" and passes through the Sun (and us within a sensible tolerance). Quite a difference.
[/quote]
The solar system has an analogous definition which conceptually is the same, but maybe not estimated the same way. The solar system's "natural plane" is referred to the [url=http://en.wikipedia.org/wiki/Invariable_plane]Invariable Plane[/url]. In this reference system, the ecliptic is off by 1.57°. However, determining the galaxy's "invariable plane" and it's precision depends on the estimations and assumptions. It seems a lot more difficult to determine it, e.g it appears to be defined based on visible matter and not dark matter (?). Also, defining the solar system's invariable plane and barycenter seems at least tenable based on it's relatively near-zero finite size compared to the galaxy.
[quote="Wikipedia"]
... The [color=#0000FF]invariable plane [/color]of a planetary system, also called Laplace's invariable plane, [b][color=#0000FF]is the plane passing through its barycenter (center of mass) perpendicular to its angular momentum vector[/color][/b]. In the Solar System, about 98% of this effect is contributed by the orbital angular momenta of the four jovian planets (Jupiter, Saturn, Uranus, and Neptune). The invariable plane is within 0.5° of the orbital plane of Jupiter,[1] and may be regarded as the weighted average of all planetary orbital and rotational planes.[/quote]
In the picture below, the galactic equator (as we are used to thinking of it) is equivalent to the Earth's ecliptic which passes through the Sun's center. The "Galactic Plane" is what I conceptually associate to the Invariable Plane. Other than looking at snapshot of observable mass distribution, I don't know how it is exactly determined.
[attachment=0]Galactic Planes.png[/attachment]