Optical Clock and Drag-Free Requirements for a Shapiro Time-Delay Mission
暂无分享,去创建一个
In the next decade or two, extremely accurate tests of general relativity under extreme conditions are expected from gravitational wave observations of binary black hole mergers with a wide range of mass ratios. In addition, major improvements are planned in both strong and weak equivalence principle tests; clock measurements based on the ACES program on the ISS; more accurate light-bending measurements; and other new types of tests. However, whether these tests are all consistent with general relativity or not, it still appears desirable to proceed with a much improved measurement of the Shapiro time delay. A suggested approach is based on using a high-quality optical clock in a drag-free spacecraft near the sun-earth L1 point and a smaller drag-free transponder spacecraft in a two-year period solar orbit. Laser phase travel-time measurements would be made between the two spacecraft over a period of 10 or 20 days around the time when the line of sight passes through the Sun. The requirements on the optical clock stability and on the drag-free systems will be discussed. The accuracy achievable for the time-delay appears to be better than 1 part in 100 million.
[1] B. Bertotti,et al. Accurate light-time correction due to a gravitating mass , 2009, 0912.2705.
[2] L. Stringhetti,et al. Status of the ACES mission , 2009, 2009 IEEE International Frequency Control Symposium Joint with the 22nd European Frequency and Time forum.
[3] Etienne Samain,et al. Astrodynamical Space Test of Relativity Using Optical Devices I (ASTROD I)—A class-M fundamental physics mission proposal for Cosmic Vision 2015–2025 , 2008, 0802.0582.