Three-body-interaction effects on the relativistic perihelion precession for the Sun-Jupiter-Saturn system

Abstract

The relativistic perihelion precession due to the three-body interaction is derived. We consider a hierarchical coplanar three-body system, such as the Sun, Jupiter and Saturn, in which both the secondary object as the largest planet corresponding to Jupiter (mass m2) and the third one corresponding to Saturn (mass m3) orbit around the primary object corresponding to Sun (mass m1 m2 m3), where the mean orbital radius of the third body is larger than that of the secondary one (denoted as ). We investigate the post-Newtonian effects on the motion of the third body (semimajor axis a, eccentricity e for the Keplerian orbital elements). Under some assumptions with a certain averaging, the relativistic perihelion precession of the third mass by the post-Newtonian three-body interaction is expressed as 6 G m2 2 c-2 a-3 n (1+9e2/16) (1-e2)-3 , where G and c denote the gravitational constant and the speed of light, respectively, and the mean motion for the third body is denoted as n = 2π a3/2 G-1/2 (m1+m2)-1/2. For the Sun-Jupiter-Saturn system, it is 7.8 × 10-6 arcsec/cy. This is larger than the Lense-Thirring effect by Sun but it cannot yet explain the recently reported value for the anomalous perihelion precession of Saturn as -0.006 0.002 arcsec/cy by Iorio (2009) based on the analyses by Pitjeva with the EPM2008 ephemerides.