This paper describes a precise measurement of electron scattering off the proton at momentum transfers of 0.003 Q 2 1 GeV 2 . The average point-to-point error of the cross sections in this experiment is ∼0.37%. These data are used for a coherent new analysis together with all world data of unpolarized and polarized electron scattering from the very smallest to the highest momentum transfers so far measured. The extracted electric and magnetic form factors provide new insight into their exact shape, deviating from the classical dipole form, and of structure on top of this gross shape. The data reaching very low Q 2 values are used for a new determination of the electric and magnetic radii. An empirical determination of the two-photon-exchange correction is presented. The implications of this correction on the radii and the question of a directly visible signal of the pion cloud are addressed.
New precise results of a measurement of the elastic electron-proton scattering cross section performed at the Mainz Microtron MAMI are presented. About 1400 cross sections were measured with negative four-momentum transfers squared up to Q² = 1 (GeV/c)² with statistical errors below 0.2%. The electric and magnetic form factors of the proton were extracted by fits of a large variety of form factor models directly to the cross sections. The form factors show some features at the scale of the pion cloud. The charge and magnetic radii are determined to be
A massive, but light abelian U (1) gauge boson is a well motivated possible signature of physics beyond the Standard Model of particle physics. In this paper, the search for the signal of such a U (1) gauge boson in electron-positron pair-production at the spectrometer setup of the A1 Collaboration at the Mainz Microtron (MAMI) is described. Exclusion limits in the mass range of 40 MeV/c 2 up to 300 MeV/c 2 with a sensitivity in the mixing parameter of down to 2 = 8 × 10 −7 are presented. A large fraction of the parameter space has been excluded where the discrepancy of the measured anomalous magnetic moment of the muon with theory might be explained by an additional U (1) gauge boson.
The experimental data obtained from the reaction of 6 Li projectiles at 2A GeV on a fixed graphite target were analyzed to study the invariant mass distributions of d + π − and t + π − . Indications of a signal in the d + π − and t + π − invariant mass distributions were observed with significances of 5.3 σ and 5.0 σ , respectively, when including the production target, and 3.7 σ and 5.2 σ , respectively, when excluding the target. The estimated mean values of the invariant mass for d + π − and t + π − signal were 2059.3 ± 1.3 ± 1.7 MeV/c 2 and 2993.7 ± 1.3 ± 0.6 MeV/c 2 respectively. The lifetime estimation of the possible bound states yielding to d + π − and t + π − final states were deduced to be as 181 +30 −24 ± 25 ps and 190 +47 −35 ± 36 ps, respectively. Those final states may be interpreted as the two-body and three-body decay modes of a neutral bound state of two neutrons and a hyperon, 3 n.A hypernucleus, a subatomic system with at least one bound hyperon, is studied in order to deduce the information about fundamental hyperon (Y )-nucleon (N) and Y -Y interactions. Hypernuclei have been mainly studied by means of the missing-mass experiments with secondary-meson and primary-electron beams [1] and earlier with emulsion techniques and bubble chambers [2]. In these experiments, a variety of hypernuclei with the lightest hyperon, the hyperon, were produced and identified. However, the isospin of the produced hypernuclei is similar to that of the target nucleus in these experiments, since they are produced by the elementary process of converting one nucleon in the target nucleus into a hyperon.Information on the Λ-N interaction was already inferred from the hypernuclei in the vicinity of the β stability line * c.rappold@gsi.de † t.saito@gsi.de [3][4][5][6]. The nature of the Λ-N interaction for neutron-rich hypernuclei, in which the ΛN -ΣN coupling three-body force may play a role as described theoretically in Refs. [7-11], has not yet been studied in detail since only a few cases were observed, 10 Li [12], 7 He [13], and 6 H [14]. We thus search for other neutron-rich hypernuclei by means of induced reactions of heavy-ion beams.Neutron-and proton-rich hypernuclei can be indeed studied by using projectile fragmentation reactions of heavy-ion beams. In such reactions, a projectile fragment can capture a hyperon produced in the hot participant region to produce a hypernucleus [15][16][17][18][19]. They might also be produced in a multistage process, such as through a Fermi breakup decay of excited heavier hypernuclear spectators, possibly formed in peripheral collisions [19][20][21].We, the HypHI Collaboration, have proposed a series of experiments at the GSI Helmholtz Centre for Heavy Ion Research that would use induced reactions of stable heavy-ion beams and rare-isotope beams to produce 041001-1 0556-2813/2013/88(4)/041001 (6)
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