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@ARTICLE{Chauhan:483405,
author = {Chauhan, Ankur and Viera, Manuel Del Rio and Eckstein,
Doris and Feindt, Finn and Gregor, Ingrid-Maria and Hansen,
Karsten and Huth, Lennart and Mendes, Larissa and Mulyanto,
Budi and Rastorguev, Daniil and Reckleben, Christian and
Daza, Sara Ruiz and Schütze, Paul and Simancas, Adriana and
Spannagel, Simon and Stanitzki, Marcel and Velyka,
Anastasiia and Vignola, Gianpiero and Wennlöf, Håkan},
title = {{T}owards a {N}ew {G}eneration of {M}onolithic {A}ctive
{P}ixel {S}ensors},
reportid = {PUBDB-2022-05293, arXiv:2210.09810},
year = {2022},
note = {3 pages, 2 figures, presented at 15th Pisa Meeting on
Advanced Detectors},
abstract = {A new generation of Monolithic Active Pixel Sensors (MAPS),
produced in a 65 nm CMOS imaging process, promises higher
densities of on-chip circuits and, for a given pixel size,
more sophisticated in-pixel logic compared to larger feature
size processes. MAPS are a cost-effective alternative to
hybrid pixel sensors since flip-chip bonding is not
required. In addition, they allow for significant reductions
of the material budget of detector systems, due to the
smaller physical thicknesses of the active sensor and the
absence of a separate readout chip. The TANGERINE project
develops a sensor suitable for future Higgs factories as
well as for a beam telescope to be used at beam-test
facilities. The sensors will have small collection
electrodes (order of $\mu$m) to maximize the signal-to-noise
ratio, which makes it possible to minimize power dissipation
in the circuitry. The first batch of test chips, featuring
full front-end amplifiers with Krummenacher feedback, was
produced and tested at the Mainzer Mikrotron (MAMI) at the
end of 2021. MAMI provides an electron beam with currents up
to 100 $\mu$A and an energy of 855 MeV. The analog output
signal of the test chips was recorded with a high bandwidth
oscilloscope and used to study the charge-sensitive
amplifier of the chips in terms of waveform analysis. A beam
telescope was used as a reference system to allow for
track-based analysis of the recorded data.},
keywords = {detector, pixel (INSPIRE) / semiconductor detector, pixel
(INSPIRE) / matter, geometry (INSPIRE) / pixel, size
(INSPIRE) / electron, beam (INSPIRE) / density, high
(INSPIRE) / amplifier (INSPIRE) / Mainz Linac (INSPIRE) /
feedback (INSPIRE) / hybrid (INSPIRE) / readout (INSPIRE) /
imaging (INSPIRE) / logic (INSPIRE) / dissipation (INSPIRE)
/ electrode (INSPIRE) / Higgs-factory (INSPIRE)},
cin = {ATLAS / FHTestBeam / FTX / FEC},
ddc = {530},
cid = {I:(DE-H253)ATLAS-20120731 / I:(DE-H253)FHTestBeam-20150203
/ I:(DE-H253)FTX-20210408 / I:(DE-H253)FEC-20120731},
pnm = {611 - Fundamental Particles and Forces (POF4-611)},
pid = {G:(DE-HGF)POF4-611},
experiment = {EXP:(DE-H253)TestBeamline21-20150101},
typ = {PUB:(DE-HGF)25},
eprint = {2210.09810},
howpublished = {arXiv:2210.09810},
archivePrefix = {arXiv},
SLACcitation = {$\%\%CITATION$ = $arXiv:2210.09810;\%\%$},
doi = {10.3204/PUBDB-2022-05293},
url = {https://bib-pubdb1.desy.de/record/483405},
}
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