Yield and performance validation of the Monolithic Stitched Sensor (MOSS), the first wafer-scale prototype for the ALICE ITS3 upgrade
Abstract: The ALICE Inner Tracking System upgrade (ITS3) will employ stitched, wafer-scale Monolithic Active Pixel Sensors (MAPS) for the first time in high-energy physics, achieving a material budget of only 0.09$\,$%$\,$X$\mathrm{{0}}$ per layer. Its first stitched prototype, the Monolithic Stitched Sensor (MOSS), underwent serial testing confirming sensor yield compliance with ITS3 requirements. In-beam tests show the device meets the ITS3 efficiency requirement of >$\,$99$\,$% while maintaining a fake-hit rate below 0.1$\,$hits/pixel/s, with performance sustained up to irradiation levels of 4$\,$kGy and $4\times10{12}$1MeV$\,$n$\mathrm{{eq}}\,$cm$\mathrm{{-2}}$. The sensor demonstrates excellent charge-collection properties and linearity between time-over-threshold and deposited energy in the 1.8 - 6.5$\,$keV range in response to soft X-ray emissions. This article provides an overview of the validation steps and characterisation results.
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