| Página principal > Cryogenic technology for tracking detectors |
| Article | |
| Title | Cryogenic technology for tracking detectors |
| Author(s) | Granata, V ; Da Vià, C ; Watts, S ; Borer, K ; Janos, S ; Pretzl, Klaus P ; Dezillie, B ; Li, Z ; Casagrande, L ; Collins, P ; Grohmann, S ; Heijne, Erik H M ; Lourenço, C ; Niinikoski, T O ; Palmieri, V G ; Sonderegger, P ; Borchi, E ; Bruzzi, Mara (INFN and Universita', Firenze, Italy) ; Pirollo, S ; Chapuy, S ; Dimcovski, Zlatomir ; Grigoriev, E ; Bell, W ; Devine, S R H ; O'Shea, V ; Ruggiero, G ; Smith, K ; Berglund, P ; de Boer, Wim ; Hauler, F ; Heising, S ; Jungermann, L ; Abreu, M C ; Rato-Mendes, P ; Sousa, P ; Cindro, V ; Mikuz, M ; Zavrtanik, M ; Esposito, A P ; Konorov, I ; Paul, S ; Buontempo, S ; D'Ambrosio, D ; Pagano, S ; Eremin, V V ; Verbitskaya, E |
| Affiliation | (Brunel Univ) |
| Publication | 2001 |
| In: | Nucl. Instrum. Methods Phys. Res., A 461 (2001) 197-9 |
| DOI | 10.1016/S0168-9002(00)01205-5 |
| Subject category | Detectors and Experimental Techniques |
| Accelerator/Facility, Experiment | RD39 |
| Abstract | A low-mass cryogenic cooling technique for silicon sensor modules has been developed in the framework of the RD39 Collaboration at CERN. A prototype low-mass beam tracker cryostat has been designed, constructed and tested for applications in fixed target experiments. We shall report here briefly the main features and results of the system. (2 refs). |