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Lattice QCD results for the topological up-quark mass contribution: too small to rescue the m_u=0 solution to the strong CP problem

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arxiv 2111.00288 v2 pith:N46OMC3C submitted 2021-10-30 hep-lat hep-ph

Lattice QCD results for the topological up-quark mass contribution: too small to rescue the m_u=0 solution to the strong CP problem

classification hep-lat hep-ph
keywords masscontributiontopologicallatticeproblemresultssolutionstrong
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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A vanishing Yukawa coupling of the up quark could in principle solve the strong CP problem. To render this solution consistent with current algebra results, the up quark must receive an alternative mass contribution that conserves CP symmetry. Such a contribution could be provided by QCD through non-perturbative topological effects, including instantons. In this talk, we present the first direct lattice computation of this topological mass contribution, using gauge configurations generated by the Extended Twisted Mass collaboration. We use the Iwasaki gauge action, Wilson twisted mass fermions at maximal twist, and dynamical up, down, strange and charm quarks. Our result for the topological mass contribution is an order of magnitude too small to account for the phenomenologically required up-quark mass. This rules out the "massless" up-quark solution to the strong CP problem, in accordance with previous results relying on $\chi$PT fits to lattice data. The talk is based on [Alexandrou et al., PRL 125, 232001 (2020)], where more details can be found.

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