Characterisation of analogue MAPS produced in the 65 nm TPSCo process

TL;DR

This paper characterizes 65 nm TPSCo MAPS sensors, demonstrating their charge collection, spatial resolution, and efficiency, validating the process for future particle detection applications.

Contribution

It provides detailed characterization of the CE-65v2 MAPS sensor, exploring process modifications and their impact on performance, which is novel for this CMOS process in particle detection.

Findings

Matrix gain uniformity within 5% across configurations

Achieved spatial resolution under 2 micrometers

Over 99% efficiency at 180 e- seed threshold

Abstract

Within the context of the ALICE ITS3 collaboration, a set of MAPS small-scale test structures were developed using the 65 nm TPSCo CMOS imaging process with the upgrade of the ALICE inner tracking system as its primary focus. One such sensor, the Circuit Exploratoire 65 nm (CE-65), and its evolution the CE-65v2, were developed to explore charge collection properties for varying configurations including collection layer process (standard, blanket, modified with gap), pixel pitch (15, 18, \SI{22.5}{\micro\meter}), and pixel geometry (square vs hexagonal/staggered). In this work the characterisation of the CE-65v2 chip, based on $^{55}$Fe lab measurements and test beams at CERN SPS, is presented. Matrix gain uniformity up to the $\mathcal{O}$(5\%) level was demonstrated for all considered chip configurations. The CE-65v2 chip achieves a spatial resolution of under \SI{2}{\micro\meter} during beam tests. Process modifications allowing for faster charge collection and less charge sharing result in decreased spatial resolution, but a considerably wider range of operation, with both the \SI{15}{\micro\meter} and \SI{22.5}{\micro\meter} chips achieving over 99\% efficiency up to a $\sim$180 e$^{-}$ seed threshold. The results serve to validate the 65 nm TPSCo CMOS process, as well as to motivate design choices in future particle detection experiments.