Potential Capabilities of Lunar Laser Ranging for Geodesy and Relativity

TL;DR

Lunar Laser Ranging over 35 years provides valuable data for geodesy and tests of relativity, including lunar and Earth parameters, gravitational physics experiments, and reference frame realizations.

Contribution

This paper reviews the capabilities of LLR for geodesy and relativity, highlighting recent accuracy, modeling, and future improvements to maximize scientific potential.

Findings

LLR accurately determines Earth and lunar parameters.

LLR tests fundamental physics principles like the equivalence principle.

LLR contributes to Earth's orientation and lunar interior studies.

Abstract

Lunar Laser Ranging (LLR), which has been carried out for more than 35 years, is used to determine many parameters within the Earth-Moon system. This includes coordinates of terrestrial ranging stations and that of lunar retro-reflectors, as well as lunar orbit, gravity field, and its tidal acceleration. LLR data analysis also performs a number of gravitational physics experiments such as test of the equivalence principle, search for time variation of the gravitational constant, and determines value of several metric gravity parameters. These gravitational physics parameters cause both secular and periodic effects on the lunar orbit that are detectable with LLR. Furthermore, LLR contributes to the determination of Earth orientation parameters (EOP) such as nutation, precession (including relativistic precession), polar motion, and UT1. The corresponding LLR EOP series is three decades long. LLR can be used for the realization of both the terrestrial and selenocentric reference frames. The realization of a dynamically defined inertial reference frame, in contrast to the kinematically realized frame of VLBI, offers new possibilities for mutual cross-checking and confirmation. Finally, LLR also investigates the processes related to the Moon's interior dynamics. Here, we review the LLR technique focusing on its impact on Geodesy and Relativity. We discuss the modern observational accuracy and the level of existing LLR modeling. We present the near-term objectives and emphasize improvements needed to fully utilize the scientific potential of LLR.