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Study of CMOS strip sensor for future silicon tracker. / Han, Y.; Zhu, H.; Affolder, A. et al.
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Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, Vol. 981, 164520, 21.11.2020.
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Han, Y, Zhu, H, Affolder, A, Arndt, K, Bates, R, Benoit, M, Di Bello, F, Blue, A, Bortoletto, D, Buckland, M, Buttar, C, Caragiulo, P, Chen, Y, Das, D, Doering, D, Dopke, J, Dragone, A, Ehrler, F, Fadeyev, V, Fedorko, W, Galloway, Z, Gay, C, Grabas, H, Gregor, IM, Grenier, P, Grillo, A, Hiti, B, Hoeferkamp, M, Hommels, LBA, Huffman, T, John, J, Kanisauskas, K, Kenney, C, Kramberger, G, Liu, P, Lu, W, Liang, Z, Mandić, I, Maneuski, D, Martinez-Mckinney, F, McMahon, S, Meng, L, Mikuz̆, M
, Muenstermann, D, Nickerson, R, Peric, I, Phillips, P, Plackett, R, Rubbo, F, Ruckman, L, Segal, J, Seidel, S, Seiden, A, Shipsey, I, Song, W, Stanitzki, M, Su, D, Tamma, C, Turchetta, R, Vigani, L, Volk, J, Wang, R, Warren, M, Wilson, F, Worm, S, Xiu, Q & Zhang, J 2020, '
Study of CMOS strip sensor for future silicon tracker',
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 981, 164520.
https://doi.org/10.1016/j.nima.2020.164520APA
Han, Y., Zhu, H., Affolder, A., Arndt, K., Bates, R., Benoit, M., Di Bello, F., Blue, A., Bortoletto, D., Buckland, M., Buttar, C., Caragiulo, P., Chen, Y., Das, D., Doering, D., Dopke, J., Dragone, A., Ehrler, F., Fadeyev, V., ... Zhang, J. (2020).
Study of CMOS strip sensor for future silicon tracker.
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment,
981, Article 164520.
https://doi.org/10.1016/j.nima.2020.164520Vancouver
Han Y, Zhu H, Affolder A, Arndt K, Bates R, Benoit M et al.
Study of CMOS strip sensor for future silicon tracker.
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. 2020 Nov 21;981:164520. Epub 2020 Aug 11. doi: 10.1016/j.nima.2020.164520
Author
Bibtex
@article{1b5308db6101489a90a40175020118e8,
title = "Study of CMOS strip sensor for future silicon tracker",
abstract = "Monolithic silicon sensors developed with High-Voltage CMOS (HV-CMOS) processes have become highly attractive for charged particle tracking. Compared with the standard CMOS sensors, HV-CMOS sensors can provide larger and deeper depletion regions that lead to larger signals and faster charge collection. They can provide high position resolution, low material budget, high radiation hardness and low cost that are desirable for high performance tracking in harsh collision environment. Various studies have been conducted to explore the technology feasibility for the large-area tracking systems at future collider experiments. CHESS (CMOS HV/HR Evaluation for Strip Sensor) sensor series have been developed as an alternative solution to the conventional silicon micro-strip detectors for the ATLAS inner tracker upgrade. The first prototype (named CHESS1) was to evaluate the diode geometry and the in-pixel analog electronics. Obtained test results were used to optimize the second prototype (named CHESS2). CHESS2 was implemented with a full digital readout architecture and realized as a full reticle sized monolithic sensor. In this paper, the basic characteristics of the CHESS2 prototype sensors and their performance in response to different input signals are presented. ",
keywords = "CHESS, High-Voltage CMOS, Large-area tracking system, Monolithic silicon sensor, Budget control, Charged particles, Costs, Silicon detectors, Alternative solutions, Analog electronics, Basic characteristics, High performance tracking, Monolithic sensors, Position resolution, Radiation hardness, Silicon micro-strip detectors, CMOS integrated circuits",
author = "Y. Han and H. Zhu and A. Affolder and K. Arndt and R. Bates and M. Benoit and {Di Bello}, F. and A. Blue and D. Bortoletto and M. Buckland and C. Buttar and P. Caragiulo and Y. Chen and D. Das and D. Doering and J. Dopke and A. Dragone and F. Ehrler and V. Fadeyev and W. Fedorko and Z. Galloway and C. Gay and H. Grabas and I.M. Gregor and P. Grenier and A. Grillo and B. Hiti and M. Hoeferkamp and L.B.A. Hommels and T. Huffman and J. John and K. Kanisauskas and C. Kenney and G. Kramberger and P. Liu and W. Lu and Z. Liang and I. Mandi{\'c} and D. Maneuski and F. Martinez-Mckinney and S. McMahon and L. Meng and M. Miku{\u z} and D. Muenstermann and R. Nickerson and I. Peric and P. Phillips and R. Plackett and F. Rubbo and L. Ruckman and J. Segal and S. Seidel and A. Seiden and I. Shipsey and W. Song and M. Stanitzki and D. Su and C. Tamma and R. Turchetta and L. Vigani and J. Volk and R. Wang and M. Warren and F. Wilson and S. Worm and Q. Xiu and J. Zhang",
note = " References: Turchetta, R., A monolithic active pixel sensor for charged particle tracking and imaging using standard VLSI CMOS technology (2001) Nucl. Instrum. Meth., 458 (3), pp. 677-689; Greiner, L., A MAPS based vertex detector for the STAR experiment at RHIC (2011) Nucl. Instrum. Meth., 650 (1), pp. 68-72; Abelev, B., Technical design report for the upgrade of the ALICE inner tracking system (2014) J. Phys. G: Nucl. Part. Phys., 41 (8); Colella, D., ALICE inner tracking system upgrade: construction and commissioning (2019); Zhang, Y., Charge collection and non-ionizing radiation tolerance of CMOS pixel sensors using a 0.18 μm CMOS process (2016) Nucl. Instrum. Meth., A831, pp. 99-104; Chen, L., Characterization of the first prototype CMOS pixel sensor developed for the CEPC vertex detector (2019) Radiat. Detect. Technol. Methods, 3, p. 45; Han, Y., Test beam measurements of an irradiated prototype pixel sensor designed for the CEPC vertex detector (2020) Nucl. Instrum. Meth., 977; Peri{\'c}, I., Kreidl, C., Fischer, P., Particle pixel detectors in high-voltage CMOS technology - New achievements (2011) Nucl. Instrum. Meth., 650 (1), pp. 158-162; Fadeyev, V., Investigation of HV/HR-CMOS technology for the ATLAS phase-II strip tracker upgrade (2016) Nucl. Instrum. Meth., 831, pp. 189-196; Huffman, B.T., Radiation hardness of two CMOS prototypes for the ATLAS HL-LHC upgrade project (2016) J. Instrum., 11 (2), p. C02005; Kanisauskas, K., Radiation hardness studies of AMS HV-CMOS 350 nm prototype chip hvstripv1 (2017) J. Instrum., 12 (2), p. P02010; Hiti, B., Charge collection studies in irradiated HV-CMOS particle detectors (2016) J. Instrum., 11 (4), p. P04007; Liang, Z., Study of built-in amplifier performance on HV-CMOS sensor for the ATLAS phase-II strip tracker upgrade (2016) Nucl. Instrum. Meth., A831, pp. 156-160; Tamma, C., The CHESS-2 prototype in AMS 0.35 μm process: A high voltage CMOS monolithic sensor for ATLAS upgrade (2016)UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85089544715&doi=10.1016%2fj.nima.2020.164520&partnerID=40&md5=2317794083abbfc7cbd3c0ca4bfbeabd",
year = "2020",
month = nov,
day = "21",
doi = "10.1016/j.nima.2020.164520",
language = "English",
volume = "981",
journal = "Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment",
issn = "0168-9002",
publisher = "ELSEVIER SCIENCE BV",
}
RIS
TY - JOUR
T1 - Study of CMOS strip sensor for future silicon tracker
AU - Han, Y.
AU - Zhu, H.
AU - Affolder, A.
AU - Arndt, K.
AU - Bates, R.
AU - Benoit, M.
AU - Di Bello, F.
AU - Blue, A.
AU - Bortoletto, D.
AU - Buckland, M.
AU - Buttar, C.
AU - Caragiulo, P.
AU - Chen, Y.
AU - Das, D.
AU - Doering, D.
AU - Dopke, J.
AU - Dragone, A.
AU - Ehrler, F.
AU - Fadeyev, V.
AU - Fedorko, W.
AU - Galloway, Z.
AU - Gay, C.
AU - Grabas, H.
AU - Gregor, I.M.
AU - Grenier, P.
AU - Grillo, A.
AU - Hiti, B.
AU - Hoeferkamp, M.
AU - Hommels, L.B.A.
AU - Huffman, T.
AU - John, J.
AU - Kanisauskas, K.
AU - Kenney, C.
AU - Kramberger, G.
AU - Liu, P.
AU - Lu, W.
AU - Liang, Z.
AU - Mandić, I.
AU - Maneuski, D.
AU - Martinez-Mckinney, F.
AU - McMahon, S.
AU - Meng, L.
AU - Mikuz̆, M.
AU - Muenstermann, D.
AU - Nickerson, R.
AU - Peric, I.
AU - Phillips, P.
AU - Plackett, R.
AU - Rubbo, F.
AU - Ruckman, L.
AU - Segal, J.
AU - Seidel, S.
AU - Seiden, A.
AU - Shipsey, I.
AU - Song, W.
AU - Stanitzki, M.
AU - Su, D.
AU - Tamma, C.
AU - Turchetta, R.
AU - Vigani, L.
AU - Volk, J.
AU - Wang, R.
AU - Warren, M.
AU - Wilson, F.
AU - Worm, S.
AU - Xiu, Q.
AU - Zhang, J.
N1 -
References: Turchetta, R., A monolithic active pixel sensor for charged particle tracking and imaging using standard VLSI CMOS technology (2001) Nucl. Instrum. Meth., 458 (3), pp. 677-689; Greiner, L., A MAPS based vertex detector for the STAR experiment at RHIC (2011) Nucl. Instrum. Meth., 650 (1), pp. 68-72; Abelev, B., Technical design report for the upgrade of the ALICE inner tracking system (2014) J. Phys. G: Nucl. Part. Phys., 41 (8); Colella, D., ALICE inner tracking system upgrade: construction and commissioning (2019); Zhang, Y., Charge collection and non-ionizing radiation tolerance of CMOS pixel sensors using a 0.18 μm CMOS process (2016) Nucl. Instrum. Meth., A831, pp. 99-104; Chen, L., Characterization of the first prototype CMOS pixel sensor developed for the CEPC vertex detector (2019) Radiat. Detect. Technol. Methods, 3, p. 45; Han, Y., Test beam measurements of an irradiated prototype pixel sensor designed for the CEPC vertex detector (2020) Nucl. Instrum. Meth., 977; Perić, I., Kreidl, C., Fischer, P., Particle pixel detectors in high-voltage CMOS technology - New achievements (2011) Nucl. Instrum. Meth., 650 (1), pp. 158-162; Fadeyev, V., Investigation of HV/HR-CMOS technology for the ATLAS phase-II strip tracker upgrade (2016) Nucl. Instrum. Meth., 831, pp. 189-196; Huffman, B.T., Radiation hardness of two CMOS prototypes for the ATLAS HL-LHC upgrade project (2016) J. Instrum., 11 (2), p. C02005; Kanisauskas, K., Radiation hardness studies of AMS HV-CMOS 350 nm prototype chip hvstripv1 (2017) J. Instrum., 12 (2), p. P02010; Hiti, B., Charge collection studies in irradiated HV-CMOS particle detectors (2016) J. Instrum., 11 (4), p. P04007; Liang, Z., Study of built-in amplifier performance on HV-CMOS sensor for the ATLAS phase-II strip tracker upgrade (2016) Nucl. Instrum. Meth., A831, pp. 156-160; Tamma, C., The CHESS-2 prototype in AMS 0.35 μm process: A high voltage CMOS monolithic sensor for ATLAS upgrade (2016)UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85089544715&doi=10.1016%2fj.nima.2020.164520&partnerID=40&md5=2317794083abbfc7cbd3c0ca4bfbeabd
PY - 2020/11/21
Y1 - 2020/11/21
N2 - Monolithic silicon sensors developed with High-Voltage CMOS (HV-CMOS) processes have become highly attractive for charged particle tracking. Compared with the standard CMOS sensors, HV-CMOS sensors can provide larger and deeper depletion regions that lead to larger signals and faster charge collection. They can provide high position resolution, low material budget, high radiation hardness and low cost that are desirable for high performance tracking in harsh collision environment. Various studies have been conducted to explore the technology feasibility for the large-area tracking systems at future collider experiments. CHESS (CMOS HV/HR Evaluation for Strip Sensor) sensor series have been developed as an alternative solution to the conventional silicon micro-strip detectors for the ATLAS inner tracker upgrade. The first prototype (named CHESS1) was to evaluate the diode geometry and the in-pixel analog electronics. Obtained test results were used to optimize the second prototype (named CHESS2). CHESS2 was implemented with a full digital readout architecture and realized as a full reticle sized monolithic sensor. In this paper, the basic characteristics of the CHESS2 prototype sensors and their performance in response to different input signals are presented.
AB - Monolithic silicon sensors developed with High-Voltage CMOS (HV-CMOS) processes have become highly attractive for charged particle tracking. Compared with the standard CMOS sensors, HV-CMOS sensors can provide larger and deeper depletion regions that lead to larger signals and faster charge collection. They can provide high position resolution, low material budget, high radiation hardness and low cost that are desirable for high performance tracking in harsh collision environment. Various studies have been conducted to explore the technology feasibility for the large-area tracking systems at future collider experiments. CHESS (CMOS HV/HR Evaluation for Strip Sensor) sensor series have been developed as an alternative solution to the conventional silicon micro-strip detectors for the ATLAS inner tracker upgrade. The first prototype (named CHESS1) was to evaluate the diode geometry and the in-pixel analog electronics. Obtained test results were used to optimize the second prototype (named CHESS2). CHESS2 was implemented with a full digital readout architecture and realized as a full reticle sized monolithic sensor. In this paper, the basic characteristics of the CHESS2 prototype sensors and their performance in response to different input signals are presented.
KW - CHESS
KW - High-Voltage CMOS
KW - Large-area tracking system
KW - Monolithic silicon sensor
KW - Budget control
KW - Charged particles
KW - Costs
KW - Silicon detectors
KW - Alternative solutions
KW - Analog electronics
KW - Basic characteristics
KW - High performance tracking
KW - Monolithic sensors
KW - Position resolution
KW - Radiation hardness
KW - Silicon micro-strip detectors
KW - CMOS integrated circuits
U2 - 10.1016/j.nima.2020.164520
DO - 10.1016/j.nima.2020.164520
M3 - Journal article
VL - 981
JO - Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
JF - Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
SN - 0168-9002
M1 - 164520
ER -
