Bottom Quark Mass from Upsilon Mesons
Abstract
The bottom quark pole mass is determined using a sum rule which relates the masses and the electronic decay widths of the mesons to large moments of the vacuum polarization function calculated from nonrelativistic quantum chromodynamics. The complete set of next-to-next-to-leading order (i.e. where is the bottom quark c.m. velocity) corrections is calculated and leads to a considerable reduction of theoretical uncertainties compared to a pure next-to-leading order analysis. However, the theoretical uncertainties remain much larger than the experimental ones. For a two parameter fit for , and the strong coupling , and using the scanning method to estimate theoretical uncertainties, the next-to-next-to-leading order analysis yields 4.74 GeV GeV and if experimental uncertainties are included at the 95% confidence level and if two-loop running for is employed. and have a sizeable positive correlation. For the running bottom quark mass this leads to 4.09 GeV GeV. If is taken as an input, the result for the bottom quark pole mass reads 4.78 GeV GeV (4.08 GeV GeV) for . The discrepancies between the results of three previous analyses on the same subject by Voloshin, Jamin and Pich, and K\"uhn et al. are clarified. A comprehensive review on the calculation of the heavy quark-antiquark pair production cross section through a vector current at next-to-next-to leading order in the nonrelativistic expansion is presented.
Keywords
Cite
@article{arxiv.hep-ph/9803454,
title = {Bottom Quark Mass from Upsilon Mesons},
author = {A. H. Hoang},
journal= {arXiv preprint arXiv:hep-ph/9803454},
year = {2008}
}
Comments
55 pages, latex, 13 postscript figures included