What does this research mean for the field?

Global analysis of current electric dipole moment (EDM) measurements using a hadronic-scale Lagrangian reveals that while some parameters are well-constrained, others lack sufficient high-precision data, and theoretical uncertainties can be effectively controlled. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to interpret the electric dipole moment measurements through a framework of effective quantum field theory.

June 5, 2026Open Access

A global view of the EDM landscape

Key Points

This research aims to interpret the electric dipole moment measurements through a framework of effective quantum field theory.
Utilized a hadronic-scale Lagrangian for interpretation of EDM measurements.
Employed the SFitter global analysis framework for data interpretation.
Assessed model constraints amidst theory uncertainties.
Certain parameters of the Lagrangian are well-constrained, indicating reliable measurements.
Some parameters lack sufficient high-precision data, leading to weaker constraints.
Theory uncertainties impact model constraints but can be managed within the global analysis.

Abstract

Permanent electric dipole moments (EDMs) are sensitive probes of the symmetry structure of elementary particles, which in turn is closely tied to the baryon asymmetry in the universe. A meaningful interpretation framework for EDM measurements has to be based on effective quantum field theory. We interpret the measurements performed to date in terms of a hadronic-scale Lagrangian, using the SFitter global analysis framework. We find that part of this Lagrangian is constrained very well, while some of the parameters suffer from too few high-precision measurements. Theory uncertainties lead to weaker model constraints, but can be controlled within the global analysis.

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