a Search for Narrow States in Radiative Upsilon Decays.

A search for new states produced in radiative (UPSILON)(1S) decays is accomplished by observing the inclusive photon energy spectrum. A narrow resonance in the energy spectrum indicates the existence of a new state X produced by the process (UPSILON) (--->) (gamma)X. The analysis is based on approximately 0.44 x 10('6) (UPSILON)(1S) events produced at the DORIS II e('+)e('-) storage ring. These data were collected with the Crystal Ball detector between April 1983 and May 1986. This analysis finds no evidence for a new state, so upper limits on the branching ratio BR((UPSILON) (- -->) (gamma)X) are derived, assuming the state X decays primarily to high-multiplicity hadronic final states. In particular, if the state X were a minimal Higgs particle, its primary decay mode would be to the heaviest fermion -antifermion pair energetically available. For the radiative (UPSILON)(1S) decays studied here, the heavy fermions would be cc or ss quark states, over most of the relevant Higgs' mass range. The resulting upper limit for BR((UPSILON)(1S) (--->) (gamma)X) is highly energy dependent but for X mass between 1.5 GeV and 8.0 GeV, the 90% confidence level upper limit is better than 8.0 x 10('-4). For a Higgs' mass near 5.0 GeV, the upper limit is about 2.0 x 10('-4) which is approximately equal to the lowest order calculation for the Wilczek mechanism. The Wilczek calculation with QCD radiative corrections predict branching ratios below the limits set here for all Higgs' masses.