G. Sette
University of Genoa
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Publication
Featured researches published by G. Sette.
IEEE Transactions on Nuclear Science | 2005
G. Ruggiero; E. Alagoz; V. Avati; V. Bassetti; V. Berardi; V. Bergholm; V. Boccone; M. Bozzo; A. Buzzo; M. G. Catanesi; R. Cereseto; S. Cuneo; M. Deile; R. de Oliveira; K. Eggert; N. Egorov; I. Eremin; F. Ferro; J. Hasi; F. Haug; R. Herzog; P. Jarron; Juha Kalliopuska; A. Kiiskinen; K. Kurvinen; A. Kok; W. Kundrat; R. Lauhakangas; M. Lokajiccek; D. Macina
Silicon detectors for the Roman Pots of the the large hadron collider TOTEM experiment aim for full sensitivity at the edge where a terminating structure is required for electrical stability. This work provides an innovative approach reducing the conventional width of the terminating structure to less than 100 /spl mu/m, still using standard planar fabrication technology. The objective of this new development is to decouple the electric behavior of the surface from the sensitive volume within a few tens of micrometers. The explanation of the basic principle of this new approach together with the experimental confirmation via electric measurements and beam test are presented in this paper, demonstrating that silicon detectors with this new terminating structure are fully operational and efficient to under 60 /spl mu/m from the die cut.
Progress of Theoretical Physics Supplement | 2012
Tamás Csörgő; G. Antchev; P. Aspell; I. Atanassov; V. Avati; J. Baechler; V. Berardi; M. Berretti; E. Bossini; M. Bozzo; P. Brogi; E. Brucken; A. Buzzo; F. S. Cafagna; M. Calicchio; M. G. Catanesi; C. E. Covault; M. Csanád; M. Deile; E. Dimovasili; M. Doubek; K. Eggert; V. Eremin; R. Ferretti; F. Ferro; A. Fiergolski; F. Garcia; S. Gianì; V. Greco; L. Grzanka
Tamas Csorgő4 for the TOTEM Collaboration: G. Antchev,∗) P. Aspell,8 I. Atanassov,8,∗)V. Avati,8 J. Baechler,8 V. Berardi,5b,5a M. Berretti,7b E. Bossini,7b M. Bozzo,6b,6a P. Brogi,7b E. Brucken,3a,3b A. Buzzo,6a F. S. Cafagna,5a M. Calicchio,5b,5a M. G. Catanesi,5a C. Covault,9 M. Csanad,4,∗∗) M. Deile,8 E. Dimovasili,8 M. Doubek,1b K. Eggert,9 V. Eremin,∗∗∗) R. Ferretti,6a,6b F. Ferro,6a A. Fiergolski,†) F. Garcia,3a S. Giani,8 V. Greco,7b,8 L. Grzanka,8,††) J. Heino,3a T. Hilden,3a,3b M. R. Intonti,5a M. Janda,1b J. Kaspar,1a,8 J. Kopal,1a,8 V. Kundrat,1a K. Kurvinen,3a S. Lami,7a G. Latino,7b R. Lauhakangas,3a T. Leszko,† E. Lippmaa,2 M. Lokajicek,1a M. Lo Vetere,6b,6a F. Lucas Rodŕiguez,8 M. Macŕi,6a L. Magaletti,5b,5a G. Magazzu,7a A. Mercadante,5b,5a M. Meucci,7b S. Minutoli,6a F. Nemes,4,∗∗) H. Niewiadomski,8 E. Noschis,8 T. Novak,4,† † †) E. Oliveri,7b F. Oljemark,3a,3b R. Orava,3a,3b M. Oriunno,8,‡) K. Osterberg,3a,3b P. Palazzi,7b A.-L. Perrot,8 E. Pedreschi,7a J. Petajajarvi,3a J. Prochazka,1a M. Quinto,5a E. Radermacher,8 E. Radicioni,5a F. Ravotti,8 E. Robutti,6a L. Ropelewski,8 G. Ruggiero,8 H. Saarikko,3a,3b G. Sanguinetti,7a A. Santroni,6b,6a A. Scribano,7b G. Sette,6b,6a W. Snoeys,8 F. Spinella,7a J. Sziklai,4 C. Taylor,9 N. Turini,7b V. Vacek,1b M. Vitek,1b J. Welti,3a,b J. Whitmore10
Journal of Instrumentation | 2013
E. Alagoz; G. Anelli; G. Antchev; V. Avati; V. Bassetti; V. Berardi; V. Boccone; M. Bozzo; E. Brucken; A. Buzzo; M. G. Catanesi; S. Cuneo; C. Da Via; M. Deile; R. Dinapoli; K. Eggert; V. Eremin; F. Ferro; J. Hasi; F. Haug; J. Heino; P. Jarron; J. Kalliopuska; J. Kašpar; C. J. Kenney; A. Kok; V. Kundrát; K. Kurvinen; R. Lauhakangas; E. Lippmaa
The physics programme of the TOTEM experiment requires the detection of very forward protons scattered by only a few microradians out of the LHC beams. For this purpose, stacks of planar Silicon detectors have been mounted in moveable near-beam telescopes (Roman Pots) located along the beamline on both sides of the interaction point. In order to maximise the proton acceptance close to the beams, the dead space at the detector edge had to be minimised. During the detector prototyping phase, different sensor technologies and designs have been explored. A reduction of the dead space to less than 50 μm has been accomplished with two novel silicon detector technologies: one with the Current Terminating Structure (CTS) design and one based on the 3D edge manufacturing. This paper describes performance studies on prototypes of these detectors, carried out in 2004 in a fixed-target muon beam at CERNs SPS accelerator. In particular, the efficiency and accuracy in the vicinity of the beam-facing edges are discussed.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2006
E. Noschis; E. Alagoz; G. Anelli; V. Avati; V. Berardi; V. Boccone; M. Bozzo; E. Brucken; A. Buzzo; M. G. Catanesi; R. Cereseto; S. Cuneo; C. Da Via; M. Deile; R. Dinapoli; K. Eggert; N. Egorov; I. Eremin; F. Ferro; J. Hasi; F. Haug; J. Heino; P. Jarron; J. Kalliopuska; J. Kašpar; A. Kok; Y. Kozlov; W. Kundrat; K. Kurvinen; R. Lauhakangas
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2010
G. Antchev; P. Aspell; I. Atanassov; V. Avati; V. Berardi; M. Berretti; M. Bozzo; E. Brucken; A. Buzzo; F. S. Cafagna; M. Calicchio; M. G. Catanesi; M. A. Ciocci; M. Csanád; T. Csörgő; M. Deile; E. Dénes; E. Dimovasili; M. Doubek; K. Eggert; F. Ferro; F. Garcia; S. Gianì; V. Greco; L. Grzanka; J. Heino; T. E. Hilden; M. Janda; J. Kaˇspar; J. Kopal
arXiv: Instrumentation and Detectors | 2005
M. Deile; E. Alagoz; G. Anelli; G. Antchev; M. Ayache; F. Caspers; E. Dimovasili; R. Dinapoli; K. Eggert; J.L. Escourrou; O. Fochler; K. Gill; R. Grabit; F. Haug; P. Jarron; J. Kaplon; T. Kroyer; T. Luntama; D. Macina; E. Mattelon; H. Niewiadomski; L. Mirabito; E. Noschis; A. Park; A. L. Perrot; O. Pirotte; J.M. Quetsch; F. Regnier; G. Ruggiero; Shahyar Saramad
European Physical Journal C | 2004
V. Avati; V. Bergholm; V. Boccone; M. Bozzo; M. Buenerd; A. Buzzo; R. Cereseto; S. Cuneo; C. Da Via; M. Deile; K. Eggert; F. Ferro; J.P. Guillaud; J. Hasi; F. Haug; R. Herzog; P. Jarron; J. Kalliopuska; A. Kiiskinen; K. Kurvinen; A. Kok; W. Kundrat; R. Lauhakangas; M. Lokajichek; D. Macina; M. Macri; T. Maki; S. Minutoli; A. Morelli; P. Musico
Topical Workshop on Electronics for Particle Physics, TWEPP 2007 | 2007
G. Anelli; G. Antchev; V. Avati; P. Aspell; V. Berardi; U. Bottigli; M. Bozzo; E. Brucken; A. Buzzo; F. S. Cafagna; M. Calicchio; F. Capurro; M. G. Catanesi; P. Chalmet; M. A. Ciocci; M. Csanad; T. Csörgo; S. Cuneo; C. Da Via; M. Deile; E. Dimovasili; K. Eggert; F. Ferro; A. Giachero; F. Garcia; V. Greco; J. Hasi; F. Haug; J. Heino; T. E. Hilden
Progress of Theoretical Physics Supplement | 2012
G. Antchev; P. Aspell; I. Atanassov; V. Avati; J. Baechler; V. Berardi; M. Berretti; E. Bossini; M. Bozzo; P. Brogi; E. Brucken; A. Buzzo; F. S. Cafagna; M. Calicchio; M. G. Catanesi; C. E. Covault; Mate Csanad; M. Deile; E. Dimovasili; M. Doubek; K. Eggert; V. Eremin; R. Ferretti; F. Ferro; A. Fiergolski; F. Garcia; S. Gianì; V. Greco; L. Grzanka; J. Heino
Archive | 2011
G. Antchev; P. Aspell; I. Atanassov; V. Avati; J. Baechler; V. Berardi; M. Berretti; M. Bozzo; E. Br; A. Buzzo; F. S. Cafagna; M. Calicchio; M. G. Catanesi; C. E. Covault; M. Csan; M. Deile; E. Dimovasili; M. Doubek; K. Eggert; F. Ferro; A. Fiergolski; F. Garcia; S. Gianì; V. Greco; L. Grzanka; J. Heino; T. E. Hilden; M. Janda; J. Kopal; K. Kurvinen
