Author :
Schnetzer, S. ; Adam, W. ; Bauer, C. ; Berdermann, E. ; Bergonzo, P. ; Bogani, F. ; Borchi, E. ; Brambilla, A. ; Bruzzi, M. ; Colledani, C. ; Conway, J. ; Dabrowski, W. ; DaGraca, J. ; Delpierre, P. ; Deneuville, A. ; Dulinski, W. ; van Eijk, B. ; Fallou,
Author_Institution :
Rutgers Univ., Piscataway, NJ, USA
Abstract :
Recent progress on developing diamond-based sensors for vertex detection at high luminosity hadron colliders is described. Measurements of the performance of diamond sensors after irradiation to fluences of up to 5×1015 hadrons/cm2 are shown. These indicate that diamond sensors will operate at distances as close as 5 cm from the interaction point at the Large Hadron Collider (LHC) for many years at full luminosity without significant degradation in performance. Measurements of the quality of the signals from diamond sensors as well as spatial uniformity are presented. Test beam results on measurements of diamond-based microstrip and pixels devices are described
Keywords :
CVD coatings; diamond; elemental semiconductors; semiconductor counters; C; CVD diamond radiation sensors; LHC; Large Hadron Collider; diamond sensors; diamond-based microstrip devices; diamond-based pixels devices; diamond-based sensors; high luminosity colliders; high luminosity hadron colliders; spatial uniformity; vertex detection; Australia; Degradation; Insulation life; Large Hadron Collider; Microstrip; Particle beam measurements; Photonic band gap; Radiation detectors; Sensor phenomena and characterization; Testing;
