Title :
mSTAR: Testing special relativity in space using high performance optical frequency references
Author :
Schuldt, Thilo ; Saraf, Shailendhar ; Stochino, Alberto ; Doringshoff, Klaus ; Buchman, Sasha ; Cutler, Grant D. ; Lipa, John ; Tan, Si ; Hanson, John ; Jaroux, Belgacem ; Braxmaier, Claus ; Gurlebeck, Norman ; Herrmann, Sven ; Lammerzahl, Claus ; Peters,
Author_Institution :
Deutsches Zentrum fur Luft- und Raumfahrt, Inst. fur Raumfahrtsysteme, Bremen, Germany
Abstract :
The proposed space mission mini Space-Time Asymmetry Research (mSTAR) aims at a test of special relativity by performing a clock-clock comparison experiment in a low-Earth orbit. Using clocks with instabilies at or below the 1·10-15 level at orbit time, the Kennedy-Thorndike coefficient will be measured with an up to two orders of magnitude higher accuracy than the current limit set by ground-based experiments. In the current baseline design, mSTAR utilizes an optical absolute frequency reference based on molecular iodine and a length-reference based on a high-finesse optical cavity. Current efforts aim at a space compatible design of the two clocks and improving the long-term stability of the cavity reference. In an ongoing Phase A study, the feasibility of accommodating the experiment on a SaudiSat 4 bus is investigated.
Keywords :
clocks; frequency measurement; optical testing; optical variables measurement; time measurement; Kennedy-Thorndike coefficient; SaudiSat 4 bus; clock-clock comparison experiment; ground-based experiment; high-finesse optical cavity; length-reference; low-Earth orbit; mSTAR; mini space-time asymmetry research; molecular iodine; optical absolute frequency reference; space mission; special relativity testing; Cavity resonators; Frequency modulation; Laser beams; Laser stability; Orbits; Space vehicles;
Conference_Titel :
Frequency Control Symposium & the European Frequency and Time Forum (FCS), 2015 Joint Conference of the IEEE International
Print_ISBN :
978-1-4799-8865-5
DOI :
10.1109/FCS.2015.7138789
