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First-principles calculation of electroweak box diagrams from lattice QCD

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 نشر من قبل Xu Feng
 تاريخ النشر 2020
  مجال البحث
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We present the first realistic lattice QCD calculation of the $gamma W$-box diagrams relevant for beta decays. The nonperturbative low-momentum integral of the $gamma W$ loop is calculated using a lattice QCD simulation, complemented by the perturbative QCD result at high momenta. Using the pion semileptonic decay as an example, we demonstrate the feasibility of the method. By using domain wall fermions at the physical pion mass with multiple lattice spacings and volumes, we obtain the axial $gamma W$-box correction to the semileptonic pion decay, $Box_{gamma W}^{VA}big|_{pi}=2.830(11)_{mathrm{stat}}(26)_{mathrm{sys}}times10^{-3}$, with the total uncertainty controlled at the level of $sim1$%. This study sheds light on the first-principles computation of the $gamma W$-box correction to the neutron decay, which plays a decisive role in the determination of $|V_{ud}|$.



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