English

In-medium pion weak decay constants

High Energy Physics - Phenomenology 2009-11-07 v2 Nuclear Theory

Abstract

In nuclear matter, the pion weak decay constant is separated into the two components ft,fsf_t, f_s corresponding to the time and space components of the axial-vector current. Using QCD sum rules, we compute the two decay constants from the pseudoscalar-axial vector correlation function in the matter id4x eipx<ρT[dˉ(x)iγ5u(x) uˉ(0)γμγ5d(0)]ρ>i \int d^4x~ e^{ip\cdot x} < \rho| T[{\bar d}(x) i \gamma_5 u (x)~ {\bar u}(0) \gamma_\mu \gamma_5 d (0)] | \rho>. It is found that the sum rule for ftf_t satisfies the in-medium Gell-Mann--Oakes--Renner (GOR) relation precisely while the fsf_s sum rule does not. The fsf_s sum rule contains the non-negligible contribution from the dimension 5 condensate <qˉiD0iD0q>N+18<qˉgsσGq>N<{\bar q} i D_0 iD_0 q >_N + {1\over 8} < {\bar q} g_s \sigma \cdot {\cal G} q >_N in addition to the in-medium quark condensate. Using standard set of QCD parameters and ignoring the in-medium change of the pion mass, we obtain ft=105f_t =105 MeV at the nuclear saturation density. The prediction for fsf_s depends on values of the dimension 5 condensate and on the Borel mass. However, the OPE constrains that fs/ft1f_s/f_t \ge 1 , which does not agree with the prediction from the in-medium chiral perturbation theory. Depending on the value of the dimension 5 condensate, fsf_s at the saturation density is found to be in the range 112134 112 \sim 134 MeV at the Borel mass M21M^2 \sim 1 GeV2^2.

Keywords

Cite

@article{arxiv.hep-ph/0105085,
  title  = {In-medium pion weak decay constants},
  author = {Hungchong Kim},
  journal= {arXiv preprint arXiv:hep-ph/0105085},
  year   = {2009}
}

Comments

19 pages including two postscript figures, substantially revised