Testing the Concept of Quark-Hadron Duality with the ALEPH τ Decay Data

Abstract

We propose a modified procedure for extracting the numerical value for the strong coupling constant αs from the τ lepton hadronic decay rate into non-strange particles in the vector channel. We employ the concept of the quark-hadron duality specifically, introducing a boundary energy squared s p>0, the onset of the perturbative QCD continuum in Minkowski space BLR,Rafa,PPR. To approximate the hadronic spectral function in the region s>s p, we use Analytic Perturbation Theory (APT) up to the fifth order. A new feature of our procedure is that it enables us to extract from the data simultaneously the QCD scale parameter MS and the boundary energy squared s p. We carefully determine the experimental errors on these parameters which come from the errors on the invariant mass squared distribution. For the MS scheme coupling constant, we obtain αs(m2τ)=0.308 0.014 exp.. We show that our numerical analysis is more stable against higher-order corrections than the standard one. The extracted value for the duality point s p is found surprisingly stable against perturbation theory corrections s d= 1.71 0.05 exp 0.00 th\,\, GeV2.Additionally, we recalculate the "experimental" Adler function in the infrared region using final ALEPH results. The uncertainty on this function is also determined.