The high Physics sensitivity of the storage ring proton Electric Dipole Moment experiment
ORAL · Invited
Abstract
Using similar tools to the ones developed for the high precision study of the systematic errors in the muon g-2 experiment, the storage ring EDM (srEDM) collaboration has completed a comprehensive systematic errors study for an experiment sensitive at or better than the 10^-29 e-cm level. The main componenets of the ring lattice include the use of radial electric field for the beam bending, and magnetic fields for alternate gradient focusing. This hybrid design shields the beam from unwanted magnetic fields, while the (potentially serious) vertical dipole electric field systematic error source is canceled by the simultaneous clock-wise and counter-clock-wise beam storage. Implemending a strictly symmetric ring lattice significantly reduces the so-called vertical velocity and geometrical-phase effects, both rising from the inevitable misalignment of the lattice elements at below 0.1mm placement accuracy.
Furthermore, we have developed a number of strategies on how to recognize and eliminate potential systematic error sources by implementing a new method coined as spin-based alignment. Most of the above mentioned techniques are published in Omarov et al., PRD 2022.
The use of the exisiting tunnel at AGS of BNL of 805m circumference would provide an opportunity to save on construction costs, while reducing the required electric field strength to comfortable levels. The effort can reach publication level data in less than ten years from start of construction.
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Publication: Z. Omarov et al., Comprehensive Symmetric-Hybrid ring design for pEDM experiment at below 10-29e-cm, Phys. Rev. D 105, 032001 (2022)<br>On Kim et al., New method of probing an oscillating EDM induced by axion-like dark matter…, Phys. Rev. D 104 (9), 096006 (2021)<br>P.W. Graham et al., Storage ring Probes for Dark Matter and Dark Energy, Phys. Rev. D 103 (5), 055010 (2021)<br>S. Haciomeroglu and Y.K. Semertzidis, Hybrid ring design in the storage-ring proton EDM experiment, Phys. Rev. Accel. Beams 22 (3), 034001 (2019)<br>S.P. Chang et al., Axion-like dark matter search using the storage ring EDM method, Phys. Rev. D 99 (8), 083002 (2019)<br>S. Haciomeroglu et al., SQUID-based Beam Position Monitor, PoS ICHEP2018 (2019) 279<br>N. Hempelmann et al., Phase locking the spin precession in a storage ring, Phys. Rev. Lett. 119 (1), 014801 (2017)<br>G. Guidoboni et al., How to reach a Thousand-second in-plane Polarization Lifetime with 0.97 GeV/c Deuterons in a storage ring, Phys. Rev. Lett. 117 (5), 054801 (2016)<br>V. Anastassopoulos et al., A storage ring experiment to detect a proton electric dipole moment, Rev. Sci. Instrum. 87 (11), 115116 (2016)<br>E.M. Metodiev et al., Analytical benchmarks for precision particle tracking in electric and magnetic rings, NIM A797, 311 (2015)<br>E.M. Metodiev et al., Fringe electric fields of flat and cylindrical deflectors in electrostatic charged particle storage rings, Phys. Rev. Accel. Beams 17 (7), 074002 (2014)<br>W.M. Morse et al., rf Wien filter in an electric dipole moment storage ring: The "partially frozen spin" effect, Phys. Rev. Accel. Beams 16 (11), 114001 (2013)<br>N.P.M. Brantjes et al., Correction systematic errors in high-sensitivity deuteron polarization measurements, Nucl. Instrum. Meth. A664, 49 (2012)<br>G.W. Bennett et al., An improved limit on the muon electric dipole moment, Phys. Rev. D 80, 052008 (2009)<br>F.J.M. Farley et al., A new method of measuring electric dipole moments in storage rings, Phys. Rev. Lett. 93, 052001 (2004)
Presenters
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Yannis K Semertzidis
KAIST
Authors
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Yannis K Semertzidis
KAIST