Analytically calculated post-Keplerian range and range-rate perturbations: the solar Lense-Thirring effect and BepiColombo

Abstract

We analytically calculate the time series for the perturbations (t),~(t) induced by a general disturbing acceleration A on the mutual range and range-rate of two test particles A,~B orbiting the same spinning body. We apply it to the general relativistic Lense-Thirring effect, due to the primary's spin S, and the classical perturbation arising from its quadrupole mass moment J2 for arbitrary orbital geometries and orientation of the source's symmetry axis S. The Earth-Mercury range and range-rate are nominally affected by the Sun's gravitomagnetic field to the 10~m,~10-3~cm s-1 level, respectively, during the extended phase (2026-2028) of the forthcoming BepiColombo mission to Mercury whose expected tracking accuracy is of the order of 0.1~m,~2× 10-4~cm s-1. The competing signatures due to the solar quadrupole J2, if modelled at the σJ2 10-9 level of the latest planetary ephemerides INPOP17a, are nearly 10 times smaller than the relativistic gravitomagnetic effects. The position and velocity vectors r,~v of Mercury and Earth are changed by the solar Lense-Thirring effect by about 10~m,~1.5~m and 10-3~cm s-1,~10-5~cm s-1, respectively, over 2 yr; neglecting such shifts may have an impact on long-term integrations of the inner solar system dynamics over Gyr timescales.