Observable frequency shifts via spin-rotation coupling

The consequences of spin-rotation-gravity coupling are worked out for linear gravitational waves. The coupling of helicity of the wave with the rotation of a gravitational-wave antenna is investigated and the resulting modifications in the Doppler effect and aberration are pointed out for incident high-frequency gravitational radiation. Extending these results to the case of a gravitomagnetic field via the gravitational Larmor theorem, the rotation of linear polarization of gravitational radiation propagating in the field of a rotating mass is studied. It is shown that in this case the linear polarization state rotates by twice the Skrotskii angle as a consequence of the spin-2 character of linear gravitational waves.

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“…This expression is the exact spin-2 analog of the electromagnetic result [8,9] that has been observationally verified for ! .…”

Section: Helicity-rotation Couplingsupporting

confidence: 59%

Helicity-rotation-gravity coupling for gravitational waves

Ramos

Mashhoon

2006

Phys. Rev. D

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“…It seems reasonable to have two (rather than one as suggested in [23]) rotating spin-flippers. Signals should be absent if they are rotated in the same directions.…”

Section: Experiments With Atoms and Cold Neutronsmentioning

confidence: 91%

Equivalence principle and experimental tests of gravitational spin effects

2007

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We study the possibility of experimental testing the manifestations of equivalence principle in spin-gravity interactions. We reconsider the earlier experimental data and get the first experimental bound on anomalous gravitomagnetic moment. The spin coupling to the Earth's rotation may also be explored at the extensions of neutron EDM and g−2 experiments. The spin coupling to the terrestrial gravity produces a considerable effect which may be discovered at the planned deuteron EDM experiment. The Earth's rotation should also be taken into account in optical experiments on a search for axionlike particles.

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“…JWKB) form for almost a century and is commonly referred to as the "Sagnac effect" [4]. On the other hand, the observational consequences of the intrinsic spin-rotation coupling have been explored for the past several decades [5].…”

Section: Spin-rotation Couplingmentioning

confidence: 99%

“…The general phenomenon of spin-rotation coupling for photons has been the subject of recent investigations [25]. The spin-rotation energy shift would give rise to an observable beat phenomenon in a proposed interferometry experiment [5].…”

Section: Observational Aspects Of the Spin-rotation Couplingmentioning

confidence: 99%

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Spin in Special and General Relativity

Ryder

Mashhoon

Gyros, Clocks, Interferometers...: Testing Relativistic Graviy in Space

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General remarksBroadly speaking, the "role of spin and rotation in General Relativity" covers two topics; the behavior of spinning particles in GR -this "spin" being either classical or quantum mechanical, and the physics associated with (noninertial) rotations. The papers presented to this session cover both these aspects of the subject. To the non-specialist, the most familiar heading in this general area is the Lense-Thirring effect, a precessional effect which is predicted (though so far not observed) to take place close to a rotating body. The papers of Ciufolini and Teyssandier are both devoted to this effect. Also well-known is the (gravitomagnetic) clock effect; as its name implies, this is concerned with time nonintegrability, rather than with precession. Tartaglia and Maleki both address this topic; and we live, moreover, at a time when both the Lense-Thirring and gravitomagnetic clock effects have the enticing possibility of experimental confirmation in the near future.Connections with gravitational waves (also soon to be detected?) are made, though in very different ways by Cooperstock, Slagter, and Suzuki and Maeda. The behavior of spinning particles in various types of gravitational fields is analyzed by Mohseni, Tucker and Wang, by Mukhopadhyay and by Singh and Papini, the latter two contributions being concerned specifically with Dirac particles, while White and Raine -alone in this session -consider a theory with torsion. Bini, Gemelli and Ruffini give a more general account of the description of spinning particles in GR. In a nonquantum context, Wu and Xu include 1

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Observable frequency shifts via spin-rotation coupling

Cited by 59 publications

References 38 publications

Helicity-rotation-gravity coupling for gravitational waves

Helicity-rotation-gravity coupling for gravitational waves

Equivalence principle and experimental tests of gravitational spin effects

Spin in Special and General Relativity

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