Investigating ultra-thin 4H-SiC AC-LGADs for superior radiation-hard timing applications

Abstract

The Low Gain Avalanche Diodes (LGADs) are promising particle detectors for timing resolution better than 50 ps under a high radiation environment. This study investigates n-in-p LGAD architecture, focusing on ultra-thin sensors of thickness less than 50\ μm using the WeightField2 program. The capabilities of WeightField2 are demonstrated by comparing its results with irradiation measurements from an FBK LGAD wafer, showing good agreement across unirradiated and neutron-irradiated conditions. This paper presents device simulations in High Luminosity LHC conditions (lifetime integrated fluence O (1014)\ neq~cm-2, temperature ≈ 243\ K ), and taking into account radiation damage, gain reduction due to fluence, and lattice defects. It is shown that a 20 μm thick sensor achieves the best timing performance. Among Silicon (Si), Diamond (C), and 4H-Silicon Carbide (4H-SiC), we found 4H-SiC to be the most promising: it provides the highest gain value for a fixed thickness and gain implant layer configuration, and best retains high charge collection value and timing capability under increasing fluence up to 50×1014\ neq~cm-2. A time resolution less than 25 ps is reported with different gain implant concentrations for a 20 μm 4H-SiC sensor. This work presents the potential of SiC-based LGADs in high-radiation collider environments.