$Ï$-meson properties at finite nuclear density
arXiv:nucl-th/9801055 · doi:10.1103/PhysRevC.58.1078
Abstract
We calculate the momentum dependence of the $Ï$-meson selfenergy based on the dispersion relation for the $ÏN$ scattering amplitude $f(Ï$) at low nuclear density. The imaginary part of $f(Ï)$ is determined from the optical theorem, while the total $ÏN$ cross section is obtained within the VDM at high energy and within the resonance model at low energy. Our numerical results indicate a sizeable broadening of the $Ï$-meson width in the medium especially for low relative momenta $p$ while the real part of the $Ï$ selfenergy is found to change its sign and becomes repulsive already at momenta above 100 MeV/c. Extrapolating to nuclear saturation density $Ï_0$ we find a dropping of the $Ï$-mass for $p \approx$ 0 in line with the QCD sumrule analysis of Hatsuda while at high energy an increase of the $Ï$-mass in line with the prediction by Eletsky and Joffe is obtained. However, when including a broadening of the baryonic resonances in the medium, the $Ï$-meson mass shift at $p \approx$ 0 becomes slightly repulsive whereas the width increases substantially.
20 pages, LaTeX, including 7 ps-figures, UGI-97-4, revised version, to be pub. in Phys. Rev. C