New Physics and Symmetry Tests with Polarized Photon Fusion and Dipole Moments

Abstract

We discuss new-physics searches and symmetry tests with dipole moments, emphasizing the role of polarization observables. As a primary benchmark, we consider polarized photon fusion in the e+ e- environment of the Super Tau-Charm Facility (STCF) and study γ γ τ+ τ- in the nearly back-to-back region, where a transverse-momentum-dependent (TMD) description provides a convenient framework for organizing polarization effects. We show that linearly polarized photons induce characteristic azimuthal asymmetries in the τ+ τ- kinematics, enabling polarization-based observables that enhance sensitivity to the τ electromagnetic dipole form factors. Moreover, CP-even and CP-odd dipole interactions can be disentangled through distinct angular structures, offering a systematic path to probe τ dipole moments with improved precision at future lepton colliders. As an illustration, we obtain an improved 2σ reach on the anomalous magnetic dipole moment, -4.6 × 10-3 < Re(aτ) < 7.0 × 10-3, reaching a precision level close to the Standard Model expectation. To place these prospects in a broader context, we briefly summarize the experimental status of dipole-moment measurements across different fermionic systems and highlight their complementarity in constraining new physics. We illustrate this interplay with supersymmetric scenarios featuring R-parity violation, in which loop-induced dipole moments provide correlated probes of CP-conserving and CP-violating interactions. Taken together, polarized photon fusion and precision dipole measurements constitute a coherent program for testing fundamental symmetries and exploring physics beyond the Standard Model.