Journal
PHYSICAL REVIEW LETTERS
Volume 111, Issue 10, Pages -Publisher
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevLett.111.102001
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Funding
- NGC IRAD
- Department of Energy
- NSF [PHY-0116146, PHY-1068712]
- Indiana University Center for Spacetime Symmetries
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Various theories beyond the standard model predict new particles with masses in the sub-eV range with very weak couplings to ordinary matter. A new P-odd and T-odd interaction between polarized and unpolarized nucleons proportional to (K) over right arrow.(r) over right arrow is one such possibility, where .(r) over right arrow is the distance between the nucleons and .(K) over right arrow is the spin of the polarized nucleon. Such an interaction involving a scalar coupling g(s) at one vertex and a pseudoscalar coupling g(p) at the polarized nucleon vertex can be induced by the exchange of spin-0 bosons. We used the NMR cell test station at Northrop Grumman Corporation to search for NMR frequency shifts in polarized Xe-129 and Xe-131 when a nonmagnetic zirconia rod is moved near the NMR cell. Long (T-2 similar to 20 s) spin-relaxation times allow precision measurements of the NMR frequency ratios, which are insensitive to magnetic field fluctuations. Combined with existing theoretical calculations of the neutron spin contribution to the nuclear angular momentum in xenon nuclei, the measurements improve the laboratory upper bound on the product g(s)g(p)(n) by 2 orders of magnitude for distances near 1 mm. The sensitivity of this technique can be increased by at least two more orders of magnitude.
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