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Ferragut, R; Belov, A S; Bonomi, G; Brusa, R S; Byakov, V M; Cabaret, L; Calloni, A; Canali, C; Carraro, C; Castelli, F; Cialdi, S; Comparat, D; Consolati, G; Dassa, L; Djourelov, N; Doser, M; Drobychev, G; Dudarev, A; Dupasquier, A; Ferrari, G; Fischer, A; Folegati, P; Fontana, A; Formaro, L; Giammarchi, M G; Gninenko, S N; Heyne, R; Hogan, S D; Jorgensen, L V; Kellerbauer, A; Krasnicky, D; Lagomarsino, V; Manuzio, G; Mariazzi, S; Matveev, V A; Morhard, C; Nebbia, G; Nedelec, P; Oberthaler, M K; Perini, D; Petracek, V; Prelz, F; Prevedelli, M; Al-Qaradawi, I Y; Quasso, F; Riccardi, C; Rohne, O; Rotondi, A; Sacerdoti, M; Sandaker, H; Sillou, D; Stepanov, S V; Stroke, H H; Testera, G; Trezzi, D; Turbabin, A V; Vaccarone, R; Villa, F; Warring, U; Zavatarelli, S; Zenoni, A; Zvezhinskij, D S
Canadian journal of physics, 01/2011, Letnik: 89, Številka: 1Journal Article
AEgIS (Antimatter experiment: gravity, interferometry, spectroscopy) is an experiment approved by CERN with the goal of studying antihydrogen physics. In AEgIS, antihydrogen will be produced by charge exchange reactions of cold antiprotons with positronium atoms excited in a Rydberg state (n > 20). In the first phase of the experiment, controlled acceleration by an electric field gradient (Stark effect) and subsequent measurement of free fall in a Moire deflectometer will allow a test of the weak equivalence principle. In a second phase, the antihydrogen will be slowed, confined, and laser-cooled to perform CPT studies and detailed spectroscopy. In the present work, after a general description of the experiment, the present status of advancement will be reviewed, with special attention to the production and excitation of positronium atoms.
