G
G. Passardi
Researcher at CERN
Publications - 8
Citations - 167
G. Passardi is an academic researcher from CERN. The author has contributed to research in topics: Xenon & Scintillation. The author has an hindex of 4, co-authored 8 publications receiving 165 citations.
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Journal ArticleDOI
Liquid xenon ionization and scintillation: Studies for a totally active vector electromagnetic calorimeter
TL;DR: In this paper, an ionization signal was detected by collecting drift electrons onto an anode mesh, and a scintillation signal by collecting photoelectons in a silicon photodiode immersed in the liquid.
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A ring imaging Cherenkov detector, the DELPHI Barrel RICH Prototype Part A: Experimental studies of the detection efficiency and the spatial resolution
R. Arnold,Paul Baillon,H.J. Besch,M. Bosteels,E. Christophel,M. Dracos,Y. Giomataris,J.L. Guyonnet,G. Passardi,Pierre Petroff,Jacques Séguinot,D. Z. Toet,J. Tocqueville,T. Ypsilantis +13 more
TL;DR: In this paper, the DELPHI Barrel RICH prototype test results were used as input data to a Monte Carlo prototype simulation, in part B, to interpret the ring imaging beam tests.
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Photosensitive gas detectors for the ring-imaging Cherenkov (RICH) technique and the delphi barrel rich prototype
R. Arnold,Paul Baillon,J.D. Berst,H.J. Besch,M. Bosteels,E. Christophel,Y. Giomataris,J.L. Guyonnet,G. Passardi,J. Seguinot,J. Tocqueville,D. Toet,T. Ypsilantis +12 more
TL;DR: The DELPHI barrel RICH detector as discussed by the authors is a photo-sensitive gas detector with a ring-imaging technique, and it has been shown to be very fast for future hadron colliders.
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A ring imaging Cherenkov detector, the DELPHI barrel RICH prototype Part B: Experimental studies of the detector performance for particle identification
R. Arnold,Paul Baillon,H.J. Besch,M. Bosteels,E. Christophel,M. Dracos,Y. Giomataris,J.L. Guyonnet,G. Passardi,Pierre Petroff,J. Seguinot,T. Ypsilantis +11 more
TL;DR: The DELPHI Barrel RICH prototype has been used for particle identification in this paper, where the results show that the prototype performance predicted by Monte Carlo simulations, as a function of the drift distance z d and the particle incidence angle θ b, have been achieved (particle identification between 0.17 and 35 GeV/c ).
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Reply to ‘Comments on “Liquid xenon ionization and scintillation studies for a totally active-vector electromagnetic calorimeter”’
TL;DR: The recent publication of Miyajima et al. as discussed by the authors strongly criticized a paper [Nucl. Instr. and Meth. A 352 (1995) 548] which we published several years ago on measurements of W and W s, the energy needed to create an electron or photon by ionization or scintillation, respectively, in liquid Xenon (LXe).