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Adam, W.; de Boer, W.; Borchi, E.; Bruzzi, M.; Colledani, C.; D’Angelo, P.; Dabrowski, V.; Dulinski, W.; van Eijk, B.; Eremin, V.; Fizzotti, F.; Frais-Kölbl, H.; Furetta, C.; Gan, K.K.; Gorisek, A.; Griesmayer, E.; Grigoriev, E.; Hartjes, F.; Hrubec, J.; Huegging, F.; Kagan, H.; Kaplon, J.; Kass, R.; Knöpfle, K.T.; Krammer, M.; Lange, W.; Logiudice, A.; Manfredotti, C.; Mathes, M.; Menichelli, D.; Mishina, M.; Moroni, L.; Noomen, J.; Oh, A.; Pernegger, H.; Pernicka, M.; Potenza, R.; Riester, J.L.; Rudge, A.; Sala, S.; Schnetzer, S.; Sciortino, S.; Stone, R.; Sutera, C.; Trischuk, W.; Velthuis, J.J.; Vincenzo, B.; Weilhammer, P.; Weingarten, J.; Wermes, N.; Zeuner, W.
Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment, 09/2006, Volume: 565, Issue: 1Journal Article
Progress in experimental particle physics in the coming decade depends crucially upon the ability to carry out experiments in high-radiation areas. In order to perform these complex and expensive experiments, new radiation hard technologies must be developed. This paper discusses the use of diamond detectors in future tracking applications and their survivability in the highest radiation environments. We present results of devices constructed with the newest polycrystalline and single crystal Chemical Vapor Deposition diamond and their tolerance to radiation.
