Quark masses using twisted mass fermion gauge ensembles

TL;DR

This paper calculates the up, down, strange, and charm quark masses using lattice QCD with twisted mass fermions, including multiple quark flavors and lattice spacings, achieving results consistent with physical values.

Contribution

It introduces a comprehensive lattice QCD analysis with twisted mass fermions for precise quark mass determination, including non-perturbative renormalization and multiple physical observables.

Findings

Quark masses in the MSbar scheme are determined with statistical and systematic errors.

Results are consistent across different lattice spacings and physical observables.

Quark mass ratios are also accurately computed.

Abstract

We present a calculation of the up, down, strange and charm quark masses performed within the lattice QCD framework. We use the twisted mass fermion action and carry out simulations that include in the sea two light mass-degenerate quarks, as well as the strange and charm quarks. In the analysis we use gauge ensembles simulated at three values of the lattice spacing and with light quarks that correspond to pion masses in the range from 350 MeV to the physical value, while the strange and charm quark masses are tuned approximately to their physical values. We use several quantities to set the scale in order to check for finite lattice spacing effects and in the continuum limit we get compatible results. The quark mass renormalization is carried out non-perturbatively using the RI'-MOM method converted into the $\overline{\rm MS}$ scheme. For the determination of the quark masses we use physical observables from both the meson and the baryon sectors, obtaining $m_{ud} = 3.636(66)(^{+60}_{-57})$~MeV and $m_s = 98.7(2.4)(^{+4.0}_{-3.2})$~MeV in the $\overline{\rm MS}(2\,{\rm GeV})$ scheme and $m_c = 1036(17)(^{+15}_{-8})$~MeV in the $\overline{\rm MS}(3\,{\rm GeV})$ scheme, where the first errors are statistical and the second ones are combinations of systematic errors. For the quark mass ratios we get $m_s / m_{ud} = 27.17(32)(^{+56}_{-38})$ and $m_c / m_s = 11.48(12)(^{+25}_{-19})$.