Your search keyword '"M. J. T. Collier"' showing total 2 results

1. The ATHENA antihydrogen apparatus

Author

Germano Bonomi, W. Joffrain, P. Genova, M. Marchesotti, D. P. van der Werf, G. Rouleau, Adriano Fontana, Niels Madsen, R. Landua, M. Macri, M. Charlton, Alessandro Variola, T. Yamazaki, J. S. Hangst, P. D. Bowe, E. Lodi-Rizzini, M. H. Holzscheiter, Hiroyuki Higaki, M. J. T. Collier, Adrian Glauser, D. Manuzio, C. Lenz Cesar, G. Testera, M. Amoretti, C. Carraro, Claude Amsler, Michael Doser, V. Filippini, M. C. Fujiwara, P. Montagna, R. Funakoshi, C. Regenfus, K.S. Fine, Ryugo S. Hayano, D. Lindelöf, H. Pruys, L. V. Jørgensen, V. Lagomarsino, J. Rochet, G. Manuzio, T. L. Watson, Petra Riedler, Alberto Rotondi, Yasunori Yamazaki, D. Grögler, and Adam Bouchta

Subjects

Physics, Nuclear and High Energy Physics, Annihilation, Detector, High resolution, Penning trap, Magnetic field, Nuclear physics, Positron, Antiproton, Physics::Accelerator Physics, High Energy Physics::Experiment, Physics::Atomic Physics, Antihydrogen, Instrumentation, Particle Physics - Experiment

Abstract

The ATHENA apparatus that recently produced and detected the first cold antihydrogen atoms is described. Its main features, which are described herein, are: an external positron accumulator, making it possible to accumulate large numbers of positrons; a separate antiproton catching trap, optimizing the catching, cooling and handling of antiprotons; a unique high resolution antihydrogen annihilation detector, allowing an clear determination that antihydrogen has been produced; an open, modular design making variations in the experimental approach possible and a “nested” Penning trap situated in a cryogenic, 3T magnetic field environment used for the mixing of the antiprotons and positrons.

Published

2004

2. Production and detection of cold antihydrogen atoms

Author

P. Montagna, Alessandro Variola, J. S. Hangst, Niels Madsen, M. Amoretti, M. Charlton, E. Lodi Rizzini, Ryugo S. Hayano, G. Testera, Germano Bonomi, D. Lindelöf, M. Marchesotti, M. H. Holzscheiter, C. Carraro, T. L. Watson, M. C. Fujiwara, Claude Amsler, K.S. Fine, Michael Doser, Alberto Rotondi, H. Pruys, R. Funakoshi, L. V. Jørgensen, V. Lagomarsino, J. Rochet, R. Landua, Petra Riedler, C. L. Cesar, D. P. van der Werf, Adriano Fontana, M. J. T. Collier, V. Filippini, G. Manuzio, P. D. Bowe, P. Genova, M. Macri, G. Rouleau, A. Bouchta, and C. Regenfus

Subjects

Physics, Physics::General Physics, Antiparticle, Multidisciplinary, CPT symmetry, Elementary particle, Particle detector, Antiproton Decelerator, Nuclear physics, Antiproton, Antimatter, High Energy Physics::Experiment, Physics::Atomic Physics, Antihydrogen

Abstract

A theoretical underpinning of the standard model of fundamental particles and interactions is CPT invariance, which requires that the laws of physics be invariant under the combined discrete operations of charge conjugation, parity and time reversal. Antimatter, the existence of which was predicted by Dirac, can be used to test the CPT theorem—experimental investigations involving comparisons of particles with antiparticles are numerous1. Cold atoms and anti-atoms, such as hydrogen and antihydrogen, could form the basis of a new precise test, as CPT invariance implies that they must have the same spectrum. Observations of antihydrogen in small quantities and at high energies have been reported at the European Organization for Nuclear Research (CERN)2 and at Fermilab3, but these experiments were not suited to precision comparison measurements. Here we demonstrate the production of antihydrogen atoms at very low energy by mixing trapped antiprotons and positrons in a cryogenic environment. The neutral anti-atoms have been detected directly when they escape the trap and annihilate, producing a characteristic signature in an imaging particle detector.

Published

2002