Test-beam Performance Results of the FASTPIX Sub-Nanosecond CMOS Pixel Sensor Demonstrator

Article
Report number	arXiv:2306.05938
Title	Test-beam Performance Results of the FASTPIX Sub-Nanosecond CMOS Pixel Sensor Demonstrator
Author(s)	Braach, Justus (CERN ; Hamburg U.) ; Buschmann, Eric (CERN) ; Dannheim, Dominik (CERN) ; Dort, Katharina (CERN ; Giessen U., Inst. Kernphys.) ; Kugathasan, Thanushan (Geneva U.) ; Munker, Magdalena (Geneva U.) ; Snoeys, Walter (CERN) ; Švihra, Peter (CERN) ; Vicente, Mateus (CERN ; Geneva U.)
Publication	2023-09-09
Imprint	2023-06-09
Number of pages	15
Note	15 pages, 15 figures, content as published in NIM A as part of a special issue for the ULITIMA 2023 conference
In:	Nucl. Instrum. Methods Phys. Res., A 1056 (2023) 168641
DOI	10.1016/j.nima.2023.168641 (publication)
Subject category	physics.ins-det ; Detectors and Experimental Techniques
Abstract	Within the ATTRACT FASTPIX project, a monolithic pixel sensor demonstrator chip has been developed in a modified 180 nm CMOS imaging process technology, targeting sub-nanosecond timing precision for single ionising particles. It features a small collection electrode design on a 25 micrometers-thick epitaxial layer and contains 32 mini matrices of 68 hexagonal pixels each, with pixel pitches ranging from 8.66 to 20 micrometers. Four pixels are transmitting an analog output signal and 64 are transmitting binary hit information. Various design variations are explored, aiming at accelerating the charge collection and making the timing of the charge collection more uniform over the pixel area. Signal treatment of the analog waveforms, as well as reconstruction of digital position, time and charge information, is carried out off-chip. This contribution introduces the design of the sensor and readout system and presents performance results for various pixel designs achieved in recent test beam measurements with external tracking and timing reference detectors. A time resolution below 150 ps is obtained at full efficiency for all pixel pitches.
Copyright/License	publication: © 2023 The Author(s). Published by Elsevier B.V. (License: CC-BY-4.0) preprint: (License: CC BY 4.0)

$Photograph of the FASTPIX chip (left), divided in four quadrants of matrices with pixel pitches I: \SI{8.66}{\um}, II: \SI{10}{\um}, III: \SI{15}{\um} and IV: \SI{20}{\um}. An exemplary picture and zoomed in details of a \SI{20}{\um} pitch matrix (right). Modified from \cite{instruments6010013}.$ $Wafer production process variants for FASTPIX represented by schematic cross-sections of the pixel unit cells, showing a cut perpendicular to the sensor surface. The standard \SI{180}{\nm} CMOS imaging process (left) and the modified process variant (right) with added low-dose n-type implant and optimizations such as a gap in the n-implant, retracted deep p-well and additional extra-deep p-well implant.$ $Overview of 32 matrices implemented on a single FASTPIX chip. The top-left scheme illustrates the parameter space of wafers produced using the standard process, below a similar representation of \numproduct{4 x 8} matrices on a chip produced in the modified process. The four quadrants are indicated by light blue roman numeral and are attributed their pixel pitch in the table on the top right. Within each quadrant two different collection electrode sizes are represented by white or hatched background. The matrices themselves are illustrated by geometrical icons colored in yellow, orange, red, or dark-red with the respective matrix number in bold white. The colorway indicates the p-well opening size of the pixel cell. The deep p-well opening and extra-deep p-well opening size is written along the outside edges of each quadrant. In case of the modified process different deep n-implant (gap) geometries are represented by the shape of the icon of a given matrix.$ Show more plots

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Record created 2023-08-22, last modified 2023-12-05

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