Abstract
We extract the neutron electric dipole moment $\vert \vec{d}_N\vert$ within the lattice QCD formalism. We analyse one ensemble of $N_f=2+1+1$ twisted mass clover-improved fermions with lattice spacing of $a \simeq 0.08 \ {\rm fm}$ and physical values of the quark masses corresponding to a pion mass $m_{\pi} \simeq 139 \ {\rm MeV}$. The neutron electric dipole moment is extracted by computing the $CP$-odd electromagnetic form factor $F_3(Q^2 \to 0)$ through small $\theta$-expansion of the action. This approach requires the calculation of the topological charge for which we employ a fermionic definition by means of spectral projectors while we also provide a comparison with the gluonic definition accompanied by the gradient flow. We show that using the topological charge from spectral projectors leads to absolute errors that are more than two times smaller than those provided when the field theoretic definition is employed. We find a value of $\vert \vec{d}_N\vert = 0.0009(24) \ \theta \ e \cdot {\rm fm}$ when using the fermionic definition, which is statistically consistent with zero.
Highlights
The discrete symmetries of parity P, charge conjugation C and time-reversal T play a significant role in the phenomenological structure of the Standard Model (SM)
The neutron electric dipole moment is extracted by computing the CP-odd electromagnetic form factor F3ðQ2 → 0Þ through small θ-expansion of the action. This approach requires the calculation of the topological charge for which we employ a fermionic definition by means of spectral projectors while we provide a comparison with the gluonic definition accompanied by the gradient flow
We show that using the topological charge from spectral projectors leads to absolute errors that are more than two times smaller than those provided when the field theoretic definition is employed
Summary
The discrete symmetries of parity P, charge conjugation C and time-reversal T play a significant role in the phenomenological structure of the Standard Model (SM). That is to say whether there is no invariance under CP parity, which can address the well-known unsolved puzzle of the origin of the imbalance of matter and antimatter in the universe. Such an imbalance between positive and negative electric charge would manifest itself as the nonvanishing of the neutron electric-dipole moment (nEDM).
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