TITLE:
Advanced Laser Retroreflectors for Astrophysics and Space Science
AUTHORS:
S. Dell’ Agnello, G. Delle Monache, R. Vittori, A. Boni, C. Cantone, E. Ciocci, M. Martini, G. Patrizi, M. Tibuzzi, G. Bianco, D. Currie, N. Intaglietta, L. Salvatori, C. Lops, S. Contessa, L. Porcelli, C. Mondaini, P. Tuscano, M. Maiello
KEYWORDS:
General Relativity, Satellite Laser Ranging (SLR), Lunar Laser Ranging (LLR), Cube Corner Retroreflectors (CCR)
JOURNAL NAME:
Journal of Applied Mathematics and Physics,
Vol.3 No.2,
January
30,
2015
ABSTRACT:
We developed advances laser
retroreflectors for solar system exploration, geodesy and for precision test of
General Relativity (GR) and new gravitational physics: a micro-reflector array
(INRRI, Instrument for landing-Roving laser Retroreflectors Investigations), a
midsize reflector array for the European Earth Observation (EO) program,
Copernicus (CORA, COpernicus laser Retroreflector Array), a large,
single-retroreflector (MoonLIGHT, Moon Laser Instrumentation for General relativity
High accuracy Tests). These laser retroreflectors will be fully characterized
at the SCF_Lab (Satellite/lunar/GNSS laser ranging/altimetry Cube/microsat
Characterization Facilities Laboratory), a unique and dedicated infrastructure
of INFN-LNF (www.lnf.infn.it/esperimenti/etrusco/). Our research program foresees several activities: 1) Developing and
characterizing the mentioned laser retroreflector devices to determine landing
accuracy, rover positioning during exploration and planetary/Moon’s surface
georeferencing. These devices will be passive, laser wavelength- independent,
long-lived reference point. INRRI will enable the performance of full-column measurement
of trace species in the Mars atmosphere by future space-borne lidars. These
measurements will be complementary to highly localized measurements made by gas
sampling techniques on the Rover or by laser back-scattering lidar techniques
on future orbiters and/or from the surface. INRRI will also support laser and
quantum communications, carried out among future Mars Orbiters and Mars Rovers.
This will be possible also because the INRRI laser retroreflectors will be
metal back-coated and, therefore, will not change the photon polarization. The
added value of INRRI is its low mass, compact size, zero maintenance and its
usefulness for any future laser altimetry, ranging, communications, atmospheric
lidar capable Mars orbiter, for virtually decades after the end of the Mars
surface mission, like the Apollo and Lunokhod lunar laser retroreflectors.
MoonLIGHT and INRRI are proposed for landings on the Moon (two Google Lunar X
Prize Missions, namely Moon Express; Russia’s Luna-27 mission, as well as
others under consideration/negotia- tion, also with the help of ASI, ESA and
other partnerships); 2) Precision tests of GR with LLR to MoonLIGHT reflectors.
Development of new fundamental gravity physics models and study of experimental
constraints to these models use also laser ranging and laser reflectors
throughout the solar system: extension of general relativity to include
Spacetime Torsion, Non-Minimal Coupling between matter and curvature (so-called
“
” theories, or NMC gravity); 3) Extension of program to:
Mars, Phobos and Deimos, Jupiter and Saturn icy/rocky moons, Near Earth Asteroids.