This contribution presents the results of an R&D study on the EXFLU1 batch, a novel concept of thin Low Gain Avalanche Diodes (LGADs) designed to achieve improved timing resolution and radiation tolerance up to 25 × 1014 neqcm−2. Sensors with different thicknesses (15, 20, 30, and 45μm) have been explored. New designs for the gain layer and guard ring structure have been investigated, along with two different doping activation methods. The sensors have been irradiated up to 25 × 1014 neqcm−2 and characterised in terms of current, capacitance, and gain to assess their radiation tolerance. Finally, 30μm LGADs were tested in a 4 GeV electron beam to evaluate their timing resolution.
Radiation-resistant thin LGADs for enhanced 4D tracking
Croci, T.;Fondacci, A.;Morozzi, A.;Passeri, D.;Moscatelli, F.;Paternoster, G.;
2026
Abstract
This contribution presents the results of an R&D study on the EXFLU1 batch, a novel concept of thin Low Gain Avalanche Diodes (LGADs) designed to achieve improved timing resolution and radiation tolerance up to 25 × 1014 neqcm−2. Sensors with different thicknesses (15, 20, 30, and 45μm) have been explored. New designs for the gain layer and guard ring structure have been investigated, along with two different doping activation methods. The sensors have been irradiated up to 25 × 1014 neqcm−2 and characterised in terms of current, capacitance, and gain to assess their radiation tolerance. Finally, 30μm LGADs were tested in a 4 GeV electron beam to evaluate their timing resolution.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
