Determination ofαsfrom energy-energy correlations ine+e−annihilation at 29 GeV
Physical review. D. Particles, fields, gravitation, and cosmology/Physical review. D. Particles and fields1988Vol. 37(11), pp. 3091–3102
Citations Over TimeTop 10% of 1988 papers
D. Wood, A. Petersen, G. S. Abrams, C. Adolphsen, C. Akerlof, J. Alexander, M. Alvarez, D. Amidei, A. Baden, J. Ballam, B. C. Barish, T. Barklow, B. A. Barnett, J. Bartelt, D. Blockus, G. Bonvicini, A. M. Boyarski, J. Boyer, B. Brabson, A. Breakstone, J.-M. Brom, F. Bulos, P. R. Burchat, D. L. Burke, F. Butler, F. Calviño, R. J. Cence, J. D. Chapman, D. Cords, D. P. Coupal, H. DeStaebler, D. E. Dorfan, J. M. Dorfan, P. S. Drell, G. J. Feldman, E. Fernández, R. C. Field, W. T. Ford, C. Fordham, R. Frey, D. Fujino, K. K. Gan, G. Gidal, L. Gladney, T. Glanzman, Michael S. Gold, G. Goldhaber, L. Golding, A. Green, P. Grosse-Wiesmann, J. S. Haggerty, G. Hanson, R. Harr, F. A. Harris, C. M. Hawkes, K. Hayes, D. Herrup, C. A. Heusch, T. Himel, Michael E. Hoenk, R. J. Hollebeek, D. P. Hutchinson, J. Hylen, W. R. Innes, M. Jaffré, J. A. Jaros, I. Juricic, J. Kadyk, D. Karlen, J. Kent, S. R. Klein, Akihiro Koide, W. Koska, W. Kozanecki, A. J. Lankford, R. R. Larsen, B. W. LeClaire, M. E. Levi, Z. Li, A. M. Litke, N. S. Lockyer, V. Lüth, C. Matteuzzi, J. A. J. Matthews, D. I. Meyer, B. D. Milliken, K. C. Moffeit, Laura Müller, J. Nash, T. J. Neep, D. Nitz, H. Ogren, R. A. Ong, K. O’Shaughnessy, S. I. Parker, C. Peck, M. Perl, M. Petradza, F. C. Porter, P. Rankin, B. Richter, K. Riles, P. C. Rowson, D. R. Rust, H. F-W. Sadrozinski, T. Schaad, T. Schalk, H. Schellman, W. B. Schmidke, A.S. Schwarz, A. Seiden, P. Sheldon, J. G. Smith, A. Snyder, E. Soderstrom, D. P. Stoker, R. Stroynowski, R. Thun, G. H. Trilling, R. Tschirhart, L. De Paula, R. Van Kooten, H. Veltman, P. Voruganti, S. R. Wagner, P. Weber, A. J. Weinstein, A. J. Weir, S. Weisz, S. L. White, E. Wicklund, D. Y. Wu, J. Yelton
Abstract
We have studied the energy-energy correlation in ${e}^{+}$${e}^{\mathrm{\ensuremath{-}}}$ annihilation into hadrons at \ensuremath{\surd}s =29 GeV using the Mark II detector at the SLAC storage ring PEP. We find to O(${\ensuremath{\alpha}}_{s}^{2}$) that ${\ensuremath{\alpha}}_{s}$=0.158\ifmmode\pm\else\textpm\fi{}0.003\ifmmode\pm\else\textpm\fi{}0.008 if hadronization is described by string fragmentation. Independent fragmentation schemes give ${\ensuremath{\alpha}}_{s}$=0.10--0.14, and give poor agreement with the data. A leading-log shower fragmentation model is found to describe the data well.
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