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S2 orbit deviates from Keplerian ellipse

David Levy

By David Levy
in Astronomy and Cosmology

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Janus
Janus

A clue here can be taken from the legends on the top and side of the diagram. Note that they are labeled in right ascension and declination, which are measurements of angle. This indicates that this d

Janus
Janus

Objects will follow Keplerian ellipses as long as all of the mass they are orbiting is contained inside a radius smaller than the periapis of the orbit. This insures that the mass effecting the orbit

Janus
Janus

It just took a little fiddling of the viewing angle of the orbit of S2 (basing the ellipse on S2's eccentricity) to get this image.     Which is very close to to the one you provided. Sag A is

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DrKrettin

DrKrettin

Posted
Posted

For those with a genuine interest in the science around this (i.e. not David Levy), just came across this web page with some good info, including a cool animation of the orbits.

http://www.galacticcenter.astro.ucla.edu/blackhole.html

 

That is cool. Is this the same phenomenon as the perihelion shift of Mercury, or something totally different?

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Strange

Strange

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That is cool. Is this the same phenomenon as the perihelion shift of Mercury, or something totally different?

 

 

I imagine largely the same, but the multi-body dynamics are probably a lot more complex in this case. (Plus there is always the hope that it might show some unexpected errors in GR...)

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imatfaal

imatfaal

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That is cool. Is this the same phenomenon as the perihelion shift of Mercury, or something totally different?

 

I think the major change in the orbit is basically what we would expect from a GR calc/model rather than a Newtonian.

 

 

 

 

I imagine largely the same, but the multi-body dynamics are probably a lot more complex in this case. (Plus there is always the hope that it might show some unexpected errors in GR...)

 

I know they run those calcs for binaries - I think you need to be able to work out the masses involved both via observation and by orbit (to compare gravitational mass and inertial). But then the fiendish ways experimentalist get around problems occuring light years away regularly baffles me

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Janus

Janus

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I imagine largely the same, but the multi-body dynamics are probably a lot more complex in this case. (Plus there is always the hope that it might show some unexpected errors in GR...)

By my calculations, S14, which should have the largest degree of precession due to GR, shifts by ~0.2 degrees per orbit. This works out to 1910 sec of arc per century, compared to Mercury's 43 sec of arc per century.

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