Abstract
We consider a nearly free falling Earth satellite where atomic wave interferometers are tied to a telescope pointing towards a faraway star. They measure the acceleration and the rotation relatively to the local inertial frame. We calculate the rotation of the telescope due to the aberrations and the deflection of the light in the gravitational field of the Earth. We show that the deflection due to the quadrupolar momentum of the gravity is not negligible if one wants to observe the Lense-Thirring effect of the Earth. We consider some perturbation to the ideal device and we discuss the orders of magnitude of the phase shifts due to the residual tidal gravitational field in the satellite and we exhibit the terms which must be taken into account to calculate and interpret the full signal. Within the framework of a geometric model, we calculate the various periodic components of the signal which must be analyzed to detect the Lense-Thirring effect. We discuss the results which support a reasonable optimism. As a conclusion we put forward the necessity of a more complete, realistic and powerful model in order to obtain a final conclusion on the theoretical feasibility of the experiment as far as the observation of the Lense-Thirring effect is involved.
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REFERENCES
Touboul, P., and Rodrigues, M. (2001). Class. Quant. Grav. 18, 2487.
[2] Nobili, A. M., Bramanti, D. L., Comandi, G., Toncelli, R., and Polacco, E. (2003). New Astron. 8, 371.
Rasel, E., Bingham, R., Bordé, C., Bouyer, P., Cadwell, M., Clairon, A., Danzmann, K., Dimarcq, N., Ertmer, W., Helmcke, J., Jentsch, C., Kent, B., Lämmerzahl, C., Landragin, A., Percival, I., Rasel, E. M., Salomon, C., Sandford, M., Schleich,W., Tourrenc, P.,Vitale, S., and Wolf, P. (2000). ESA Assessment Study Report, ESA-SCI, HYPER Hyper-Precision Cold Atom Interferometry in Space. Assessment Study Report, ESA-SCI (2000) 10.
Jentsch, C., Muellerand, T., Chelkowski, S., Rasel, E., and Ertmer, W. (2003). Verhandl. DPG (VI), 38, 167.
Oberthaler, M., Bernet, S., Rasel, E., Schmiedmayer, J., and Zeilinger, A. (1996). Phys. Rev. A 54, 3165.
Gustavson, T., Landragin, A., and Kasevich, M. (2000). Class. Quant. Grav. 17, 2385.
Le Coq, Y., Thywissen, J., Rangwala, S., Gerbier, F., Richard, R., Delannoy, G., Bouyer, P., and Aspect, A. (2001). Phys. Rev. Lett. 87, 170403.
Snadden, M., McGuirk, J., Bouyer, P., Haritos, K., and Kasevich, M. (1998). Phys. Rev. Lett. 81, 971.
Ni, W.-T., and Zimmermann, M. (1978). Phys. Rev. D 17, 1473.
Li, W.-Q., and Ni, W.-T. (1979). J. Math. Phys. 20, 1473.
Antoine, C., and Bordé, C. (2003). J. Opt. B 5, S199.
Will, C. (1981). Theory and Experiment in Gravitational Physics, Cambridge University Press, Cambridge, United Kingdom.
Marchal, C. (1996). Bulletin du Mu?eum National d'Histoire Naturelle 4ème série section C 18, 517.
Linet, B., and Tourrenc, P. (1976). Can. J. Phys. 54, 1129.
Ibáñez, J. (1983). Astron. Astrophys. 124, 175.
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Angonin-Willaime, MC., Ovido, X. & Tourrenc, P. Gravitational Perturbations on Local Experiments in a Satellite: The Dragging of Inertial Frame in the HYPER Project. General Relativity and Gravitation 36, 411–434 (2004). https://doi.org/10.1023/B:GERG.0000010485.62147.0e
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DOI: https://doi.org/10.1023/B:GERG.0000010485.62147.0e