Frequency Domain Storage Ring Method for Electric Dipole Moment Measurement (1508.04366v2)

Abstract: Precise measurement of the electric dipole moments (EDM) of fundamental charged particles would provide a significant probe of physics beyond the standard model. Any measurably large EDM would imply violation of both time reversal and parity conservation, with implications for the matter/anti-matter imbalance of the universe, not currently understood within the standard model. A frequency domain (i.e. difference of frequencies) method is proposed for measuring the EDM of electrons or protons or, with modifications, deuterons. Anticipated precision (i.e. reproducibility) is $10^{-30}\,$e-cm for the proton EDM, with comparable accuracy (i.e. including systematic error). This would be almost six orders of magnitude smaller than the present upper limit, and will provide a stringent test of the standard model. Resonant polarimetry, made practical by the large polarized beam charge, is the key (most novel, least proven) element of the method. Along with the phase-locked, rolling polarization "Koop spin wheel," resonant polarimetry measures beam polarization as amplitude rather than as intensity. The polarization roll, at 100\,Hz for example, and adjustable by a constant control current, causes spurious torques due to field errors to average to zero to high accuracy. Since these torques have been considered to be the dominant source of systematic error in truly frozen spin operation, this is a major improvement resulting from the rolling polarization. Important sources of systematic errors remain, the main one being due to Wien filter reversal uncertainty. Both electron and proton spins can be "frozen" in all-electric storage rings, and their EDM precisions should be comparable. Freezing the deuteron spin requires a superimposed electric and magnetic guide field; otherwise the rolling spin method and precision should be similar.