Heavy-Meson Bag Parameters using Gradient Flow
Abstract
We demonstrate the use of the gradient flow combined with the short flow-time expansion (GF+SFTX) as a renormalization procedure for four-quark operator matrix elements and associated bag parameters relevant to neutral heavy-meson mixing ( Q=2) and heavy-meson lifetimes ( Q=0). Using six RBC/UKQCD 2+1-flavor domain-wall fermion ensembles, we calculate for a charm-strange system with physical quark masses flowed bag parameters and match them to the MS scheme using perturbative SFTX coefficients up to next-to-next-to-leading order in QCD. We employ a multi-scale matching strategy and a renormalization-group improved flow-time evolution which allows for a reliable estimate of systematic uncertainties. For a fictitious neutral Ds meson, we obtain the Q=2 MS bag parameter BMS1(3\, GeV)=0.7673(123), consistent with existing short-distance D0 mixing determinations. For the Q=0 lifetime-ratio operator basis, we find the MS results BMS1(3\, GeV)=1.0524(97), BMS2(3\, GeV)=0.9621(71), εMS1(3\, GeV)=-0.2275(76), and εMS2(3\, GeV)=-0.0005(8). We provide conversion formulae to re-express these results for an arbitrary choice of evanescent operators. These results demonstrate that GF+SFTX can deliver precise determinations of dimension-six four-quark operators and establish a framework for future lattice computations including more complex operator bases, where the challenge of power-divergent mixing is shifted to the continuum and handled in the SFTX.
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