Production of relativistic antihydrogen atoms by pair production with positron capture

Citations Over TimeTop 19% of 1994 papers

Abstract

A beam of relativistic antihydrogen atoms, the bound state ($\overline{p}{e}^{+}$), can be created by circulating the beam of an antiproton storage ring through an internal gas target. An antiproton that passes through the Coulomb field of a nucleus of charge $Z$ will create ${e}^{+}{e}^{\ensuremath{-}}$ pairs, and antihydrogen will form when a positron is created in a bound rather than a continuum state about the antiproton. The cross section for this process is calculated to be $\ensuremath{\sim}4{Z}^{2}$ pb for antiproton momenta above 6 GeV/c. The gas target of Fermilab Accumulator experiment E760 has already produced \ensuremath{\sim}34 unobserved antihydrogen atoms, and a sample of \ensuremath{\sim}760 is expected in 1995 from the successive experiment E835. No other source of antihydrogen exists. A simple method for detecting relativistic antihydrogen is proposed and method outlined of measuring the antihydrogen Lamb shift to \ensuremath{\sim}1%.

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