Sigma Terms of Light-Quark Hadrons

Abstract

A calculation of the current-quark mass dependence of hadron masses can help in using observational data to place constraints on the variation of nature's fundamental parameters. A hadron's sigma-term is a measure of this dependence. The connection between a hadron's sigma-term and the Feynman-Hellmann theorem is illustrated with an explicit calculation for the pion using a rainbow-ladder truncation of the Dyson-Schwinger equations: in the vicinity of the chiral limit sigmapi = mpi/2. This truncation also provides a decent estimate of sigmarho because the two dominant self-energy corrections to the rho-meson's mass largely cancel in their contribution to sigmarho. The truncation is less accurate for the omega, however, because there is little to compete with an omega->rho+pi self-energy contribution that magnifies the value of sigmaomega by ~25%. A Poincare' covariant Faddeev equation, which describes baryons as composites of confined-quarks and -nonpointlike-diquarks, is solved to obtain the current-quark mass dependence of the masses of the nucleon and Delta, and thereby sigmaN and sigmaDelta. This "quark-core" piece is augmented by the "pion cloud" contribution, which is positive. The analysis yields sigmaN~60MeV and sigmaDelta~50MeV.

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