Abstract
We examine the muon's electric dipole moment d μ from a variety of theoretical perspectives. We point out that the reported deviation in the muon's g−2 can be due partially or even entirely to a new physics contribution to the muon's electric dipole moment. In fact, the recent g−2 measurement provides the most stringent bound on d μ to date. This ambiguity could be definitively resolved by the dedicated search for d μ recently proposed. We then consider both model-independent and supersymmetric frameworks. Under the assumptions of scalar degeneracy, proportionality, and flavor conservation, the theoretical expectations for d μ in supersymmetry fall just below the proposed sensitivity. However, nondegeneracy can give an order of magnitude enhancement, and lepton flavor violation can lead to d μ∼10 −22 e cm , two orders of magnitude above the sensitivity of the d μ experiment. We present compact expressions for leptonic dipole moments and lepton flavor violating amplitudes. We also derive new limits on the amount of flavor violation allowed and demonstrate that approximations previously used to obtain such limits are highly inaccurate in much of parameter space.
Highlights
Electric dipole moments (EDMs) of elementary particles are predicted to be far below foreseeable experimental sensitivity in the standard model
Current EDM bounds are already some of the most stringent constraints on new physics, and they are highly complementary to many other low energy constraints, since they require CP violation, but not flavor violation
We examine the prospects for detecting a non-vanishing muon EDM from a variety of theoretical perspectives
Summary
Electric dipole moments (EDMs) of elementary particles are predicted to be far below foreseeable experimental sensitivity in the standard model. We use exact expressions for all flavor-conserving amplitudes in this study, we provide compact expressions in the mass insertion approximation for branching ratios of radiative lepton decays and for leptonic EDMs and MDMs both with and without lepton flavor violation These include all leading supersymmetric effects and are well-suited to numerical calculations. The observed deviation from the standard model prediction for |ωa| has been assumed to arise entirely from a MDM and has been attributed to a new physics contribution of size. The effects of dμ and aμ are physically distinguishable: while aμ causes precession around the magnetic field’s axis, dμ leads to oscillation of the muon’s spin above and below the plane of motion This oscillation is detectable in the distribution of positrons from muon decay, and further analysis of the recent aμ data should tighten the current bounds on dμ. The proposed dedicated dμ search will provide a definitive answer, by either measuring a non-zero dμ or constraining the contribution of dμ to |ωa| to be insignificant
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