Laser Ranging to the Moon, Mars and Beyond

TL;DR

This paper discusses how advanced laser ranging technologies to the Moon and Mars can enhance space exploration infrastructure and enable precise tests of gravitational physics, including potential improvements in fundamental physics experiments.

Contribution

It presents current and future laser ranging capabilities, proposes a space architecture for exploration and physics tests, and discusses the design of the LATOR mission for relativistic gravity measurements.

Findings

Laser ranging can improve navigation accuracy for lunar and Martian exploration.

Optical technologies enable high-precision tests of gravitational theories.

Existing capabilities already significantly enhance fundamental physics experiments.

Abstract

Current and future optical technologies will aid exploration of the Moon and Mars while advancing fundamental physics research in the solar system. Technologies and possible improvements in the laser-enabled tests of various physical phenomena are considered along with a space architecture that could be the cornerstone for robotic and human exploration of the solar system. In particular, accurate ranging to the Moon and Mars would not only lead to construction of a new space communication infrastructure enabling an improved navigational accuracy, but will also provide a significant improvement in several tests of gravitational theory: the equivalence principle, geodetic precession, PPN parameters $\beta$ and $\gamma$, and possible variation of the gravitational constant $G$. Other tests would become possible with an optical architecture that would allow proceeding from meter to centimeter to millimeter range accuracies on interplanetary distances. This paper discusses the current state and the future improvements in the tests of relativistic gravity with Lunar Laser Ranging (LLR). We also consider precision gravitational tests with the future laser ranging to Mars and discuss optical design of the proposed Laser Astrometric Test of Relativity (LATOR) mission. We emphasize that already existing capabilities can offer significant improvements not only in the tests of fundamental physics, but may also establish the infrastructure for space exploration in the near future. Looking to future exploration, what characteristics are desired for the next generation of ranging devices, what is the optimal architecture that would benefit both space exploration and fundamental physics, and what fundamental questions can be investigated? We try to answer these questions.