6533b7d6fe1ef96bd1265b0b

RESEARCH PRODUCT

Splittings of low-lying charmonium masses at the physical point

Fermilab LatticeMilc CollaborationsCarleton DetarDaniel MohlerAndreas S. KronfeldJames N. SimoneSong-haeng Lee

subject

QuarkPhysicsParticle physics010308 nuclear & particles physicsHigh Energy Physics::LatticeHigh Energy Physics::PhenomenologyHigh Energy Physics - Lattice (hep-lat)ExtrapolationFOS: Physical sciencesLattice QCD01 natural sciencesCharm quarkGluonddc:High Energy Physics - PhenomenologyHigh Energy Physics - LatticeHigh Energy Physics - Phenomenology (hep-ph)Lattice (order)0103 physical sciencesHigh Energy Physics::ExperimentFermilab010306 general physicsHyperfine structure

description

We present high-precision results from lattice QCD for the mass splittings of the low-lying charmonium states. For the valence charm quark, the calculation uses Wilson-clover quarks in the Fermilab interpretation. The gauge-field ensembles are generated in the presence of up, down, and strange sea quarks, based on the improved staggered (asqtad) action, and gluon fields, based on the one-loop, tadpole-improved gauge action. We use five lattice spacings and two values of the light sea quark mass to extrapolate the results to the physical point. An enlarged set of interpolating operators is used for a variational analysis to improve the determination of the energies of the ground states in each channel. We present and implement a continuum extrapolation within the Fermilab interpretation, based on power-counting arguments, and thoroughly discuss all sources of systematic uncertainty. We compare our results for various mass splittings with their experimental values, namely, the 1S hyperfine splitting, the 1P-1S splitting and the P-wave spin-orbit and tensor splittings. Given the uncertainty related to the width of the resonances, we find excellent agreement.

yearjournalcountryeditionlanguage
2019-02-27
https://dx.doi.org/10.48550/arxiv.1810.09983