Abstract
The Einstein Equivalence Principle (EEP) carries a pivotal role in understanding theory of gravity and spacetime. It guarantees the gravity to be understood as geometric phenomenon. Considering gravitational coupling of matter in the standard model extension, we propose a novel scheme using frequency measurements to limit the equivalence principle violations in normal matter. The proposal consists of the comparison of high-precision clocks, comoving with the freely falling frame. The experimental comparison of identical kind of clocks on Earth surface can be used to carry out the proposed test, which allows performing simultaneous tests of weak equivalence principle and gravitational redshift. From the existing experiments of Sr optical clocks, we present a simultaneous determination of Earth-dependent parameter βE and clock-dependent parameter ξSr at the level of 10−5, and in combination with the gravitational redshift experiments and lunar laser ranging, we also obtain a limit on standard model extension coefficients for Lorentz violation. This work provides another important fundamental physics application for the continuous-improvement accuracy of atomic or optical clocks.
Highlights
Einstein’s theory of General Relativity (GR) is a cornerstone of our current understanding of the physical world
In the standard model extension (SME) frame, we demonstrate that frequency comparisons on clock experiment could limit the combination of free-falling-bodydependent parameters and clock-dependent parameters
One can not realize the test of Weak Equivalence Principle (WEP) until another measurement of GM is carried out by a experiment of different physical effect at the same time. Considering another kind of experiment, the gravitational redshift U/c2 can be measured in the clock experiments, which gives another isolated measurement of GM
Summary
Einstein’s theory of General Relativity (GR) is a cornerstone of our current understanding of the physical world. The SME is a general effective filed theory that describes the violation of local lorentz invariant and other tenets of EEP [21,22,23]. This frame introduces the body-dependent parameters and clock-dependent parameters, which break the WEP and gravitational redshift, respectively. Optical lattice clocks are the most precise measurement devices with the accuracy and stability of a few 10−18 [24,25,26] Their unprecedented performances make them to be widely used to search for new tests of fundamental physics [27,28,29,30]. The unparalleled performances of optical clock and optical fiber links make such a test possible for the first time
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