V. Matveev
Russian Academy of Sciences
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Publication
Featured researches published by V. Matveev.
Journal of Instrumentation | 2013
S. Aghion; O. Ahlén; C. Amsler; A. Ariga; T. Ariga; A. S. Belov; G. Bonomi; P. Bräunig; J. Bremer; R. S. Brusa; L. Cabaret; C. Canali; R. Caravita; F. Castelli; G. Cerchiari; S. Cialdi; D. Comparat; G. Consolati; J. H. Derking; S. Di Domizio; L. Di Noto; M. Doser; A. Dudarev; A. Ereditato; R. Ferragut; A. Fontana; P. Genova; M. Giammarchb; A. Gligorova; Sergei Gninenko
The main goal of the AEgIS experiment at CERN is to test the weak equivalence principle for antimatter. AEgIS will measure the free-fall of an antihydrogen beam traversing a moire deflectometer. The goal is to determine the gravitational acceleration with an initial relative accuracy of 1% by using an emulsion detector combined with a silicon ?-strip detector to measure the time of flight. Nuclear emulsions can measure the annihilation vertex of antihydrogen atoms with a precision of ~ 1?2 ?m r.m.s. We present here results for emulsion detectors operated in vacuum using low energy antiprotons from the CERN antiproton decelerator. We compare with Monte Carlo simulations, and discuss the impact on the AEgIS project.
arXiv: Atomic Physics | 2008
G. Testera; A. S. Belov; G. Bonomi; I. Boscolo; N. Brambilla; R. S. Brusa; Vsevolod M. Byakov; L. Cabaret; C. Canali; C. Carraro; F. Castelli; S. Cialdi; M. de Combarieu; D. Comparat; G. Consolati; N. Djourelov; M. Doser; G. Drobychev; A. Dupasquier; D. Fabris; R. Ferragut; G. Ferrari; A. Fischer; A. Fontana; P. Forget; L. Formaro; M. Lunardon; A. Gervasini; M. Giammarchi; S. N. Gninenko
The formation of the antihydrogen beam in the AEGIS experiment through the use of inhomogeneous electric fields is discussed and simulation results including the geometry of the apparatus and realistic hypothesis about the antihydrogen initial conditions are shown. The resulting velocity distribution matches the requirements of the gravity experiment. In particular it is shown that the inhomogeneous electric fields provide radial cooling of the beam during the acceleration.
Nuclear Instruments & Methods in Physics Research Section B-beam Interactions With Materials and Atoms | 2008
A. Kellerbauer; M. Amoretti; G. Bonomi; I. Boscolo; A. S. Belov; R. S. Brusa; Vsevolod M. Byakov; L. Cabaret; C. Canali; C. Carraro; F. Castelli; S. Cialdi; M. de Combarieu; D. Comparat; G. Consolati; N. Djourelov; M. Doser; G. Drobychev; A. Dupasquier; M. Büchner; G. Ferrari; P. Forget; L. Formaro; A. Gervasini; M. Giammarchi; S. N. Gninenko; G. F. Gribakin; Stephen D. Hogan; M. Jacquey; J. O. Meier
Hyperfine Interactions | 2015
G. Testera; S. Aghion; C. Amsler; A. Ariga; T. Ariga; A. S. Belov; G. Bonomi; P. Bräunig; J. Bremer; R. S. Brusa; L. Cabaret; M. Caccia; R. Caravita; F. Castelli; G. Cerchiari; K. Chlouba; S. Cialdi; D. Comparat; G. Consolati; S. Curreli; A. Demetrio; H. Derking; L. Di Noto; M. Doser; A. Dudarev; A. Ereditato; R. Ferragut; A. Fontana; S. Gerber; M. Giammarchi
Hyperfine Interactions | 2012
A. Kellerbauer; Y. Allkofer; C. Amsler; A. S. Belov; G. Bonomi; P. Bräunig; J. Bremer; R. S. Brusa; G. Burghart; L. Cabaret; C. Canali; F. Castelli; K. Chlouba; S. Cialdi; D. Comparat; G. Consolati; L. Dassa; L. Di Noto; A. Donzella; M. Doser; A. Dudarev; T. Eisel; R. Ferragut; G. Ferrari; A. Fontana; P. Genova; M. Giammarchi; A. Gligorova; Sergei Gninenko; S. Haider
Hyperfine Interactions | 2014
J. Storey; S. Aghion; O. Ahlén; C. Amsler; A. Ariga; T. Ariga; A. S. Belov; G. Bonomi; P. Bräunig; J. Bremer; R. S. Brusa; L. Cabaret; C. Canali; R. Caravita; F. Castelli; G. Cerchiari; S. Cialdi; D. Comparat; G. Consolati; J. H. Derking; S. Di Domizio; L. Di Noto; M. Doser; A. Dudarev; A. Ereditato; R. Ferragut; A. Fontana; P. Genova; M. Giammarchi; A. Gligorova
