Elliptical Orbits In The Schwarzschild Metric

In summary, it is possible to arrange for a non-circular free faller to meet a circular orbiter at two events. If the non-circular trajectory is outside of circular orbit between meetings, the non-circular free faller will age more. Conversely, if you arrange it so non-circular trajectory is inside the circular orbit between meetings, the circular orbiter will age more.
  • #1
dman12
13
0
I was just wondering how you would go about calculating the proper time for an observer following a freely falling elliptical orbit in a Schwarzschild metric.

I am happy with how to calculate the proper time for a circular orbit and was wondering whether if you had two observers start and end at the same spacetime point, for whom would more proper time elapse- one that followed a circular orbit or one that followed an elliptical orbit?
 
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  • #2
I far as I know, there aren't geodesic (i.e., freely falling) elliptical orbits. There are elliptical orbits that are non-geodesics, but, to calculate the time required for one orbit, more knowledge of the orbit is required.

Also, ven circular orbits do not "start and end at the same spacetime point", as time elapses.
 
  • #3
To add a bit to George Jones answer, non-circular orbits in SC metric never quite close (due to perihelion advance), so they are not ellipses.

You certainly can arrange for a non-circular (near elliptic) free faller to meet a circular orbiter at two events. Then, the general rule is that the if the non-circular trajectory is outside of circular orbit between meetings, the non-circular free faller will age more. Conversely, if you arrange it so non-circular trajectory is inside the circular orbit between meetings, the circular orbiter will age more.
 
  • #4
In very, very special circumstances, there are (freely falling) closed "spirograph" orbits.

A condition for a closed orbit is that the precession angle divides evenly into an integral multiple of 360 degrees, i.e., n*360/(precession angle) = m, where n and m are integers. If this is true, then the total precession after m aphelia is n times 360 degrees, hence the repetition.
 
  • #5
Here are a couple of references that might help with the calculation

Uros Kostic, Analytical time-like geodesics in Schwarzschild
space-time. General Relativity and Gravitation, 2012.
Preprint :http://arxiv.org/pdf/1201.5611v1.pdf

G. V. Kraniotis, S. B. Whitehouse,
Precession of Mercury in General Relativity, the Cosmolog-
ical Constant and Jacobi’s Inversion problem.
Preprint http://128.84.158.119/abs/astro-ph/0305181v3
 

1. What is an elliptical orbit in the Schwarzschild metric?

An elliptical orbit in the Schwarzschild metric is a type of orbit described by the equations of motion derived from the Schwarzschild metric, which is a solution to Einstein's field equations of general relativity. This type of orbit occurs when an object is moving around a central mass in a curved spacetime, such as a planet orbiting a star.

2. How is the Schwarzschild metric used to describe elliptical orbits?

The Schwarzschild metric is a mathematical model that describes the curvature of spacetime around a non-rotating, spherically symmetric mass. This metric is used to calculate the path of an object in this curved spacetime, resulting in an elliptical orbit.

3. What factors affect the shape of an elliptical orbit in the Schwarzschild metric?

The shape of an elliptical orbit in the Schwarzschild metric is primarily affected by the mass of the central object and the initial velocity of the orbiting object. The closer the object is to the central mass and the faster it is moving, the more elliptical the orbit will be.

4. Can elliptical orbits in the Schwarzschild metric be perfectly circular?

No, elliptical orbits in the Schwarzschild metric cannot be perfectly circular. This is because the Schwarzschild metric accounts for the curvature of spacetime, which causes objects to follow curved paths rather than straight lines. However, elliptical orbits with small eccentricities (close to 0) can closely resemble circular orbits.

5. How do elliptical orbits in the Schwarzschild metric differ from those in Newtonian mechanics?

Elliptical orbits in the Schwarzschild metric differ from those in Newtonian mechanics in several ways. In the Schwarzschild metric, the orbiting object's speed and distance from the central mass are not constant, and the orbit is not confined to a single plane. Additionally, the Schwarzschild metric accounts for the effects of the central mass's gravitational field on the curvature of spacetime, whereas Newtonian mechanics only considers the effects of a point mass's gravitational force.

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