Abstract. We present the results obtained from a series of e+e--coincidence measurements in heavy-ion collisions using the double-Orange fl-spectrometer at GSI. The collision systems U + U, U + Pb, and U+ Ta were investigated at bombarding energies close to and slightly above (U+Ta) the Coulomb barrier. For all systems studied, very narrow (FWHM -~ 20 keV) e +e-lines were observed in the sum-energy spectra, with kinetic energies ranging from ~555 keV to ~810keV, superimposed on a continuous distribution mainly due to uncorrelated e+e -emission. Particularly in the U + Ta system, a pronounced sum-energy line appears at ~ 634 keV, predominantly in deep-inelastic collisions. In some cases (e.g. U+ Pb) the line characteristics is consistent with a two-body decay mode of an emitter which moves with the c.m. velocity of the colliding ions. However, other lines, and in particular the 634 keV line (U+Ta), exhibit a rather isotropical opening-angle distribution whereas their energy is unequally shared between positrons and electrons, thus being in clear disagreement with this scenario. In general, the data preclude an emission from the separated (moving) nuclei, and, in the latter cases, provide evidence that the e+e--pair decay occurs in the vicinity of the Coulomb field of a third heavy (positively charged) partner having only a small transverse velocity (] v• < 0.02c) PACS: 14.60.Cd; 25.70.Cd; 25.70.Ef
lnroductionOver a decade ago, two experimental groups at GSI in Darmstadt, the ORANGE and the EPOS collaborations, have discovered the existence of a narrow (FWHM-70 keV), and unexpected, e + line in the positron spectra obtained from heavy-ion (HI) collisions near the Coulomb barrier [1,2]. The line is superimposed on continuous distributions, from quasi-atomic positron emission and Dedicated to Prof. B. Povh on the occasion of his 60th birthday from nuclear positron background, which can be determined quantitatively [3,4]. At the beginning the line was attributed to the process of spontaneous positron creation in the supercritical electric fields (that is Z, = Zproj + Ztarg > 173) of a long-lived di-nuclear complex formed in a collision with time delay [5]. Further, improved measurements of positron spectra, however, could resolve a series of narrow e + lines [6,7] which occur also in the so-called subcritical systems (Z, < 173), and, thus, exclude spontaneous positron emission as the origin of these lines.Subsequent e +e--coincidence experiments have shown that the e + lines correlate with e-lines of approximately equal energy, consistent with the assumption of a two-body decay of an emitter whose velocity distribution is small enough to give rise to a narrow line in the measured sum-energy spectra [8, 93. This has provoked the idea that a hitherto unknown neutral particle (mass~ 1.8 MeV/c2), decaying into e+e -pairs, might be involved, and a variety of theoretical models was proposed regarding its nature [10]. The situation became more complex since in various collision systems, investigated with higher experimental ...
