Current status and development of CMOS SiPM for scintillator-based radiation detectors toward all-digital sensors [Invited]

Nicola D’Ascenzo; Wentao Hu; Hui Lao; Yuexuan Hua; Bo Zhang; Lei Fang; Daoming Xi; Rui Zheng; Ao Qiu; Emanuele Antonecchia; Yiqing Ling; Yuqing Liu; Yan Li; Hang Yu; Peng Xiao; Qingguo Xie

doi:10.3788/COL202422.020021

Chinese Optics Letters, Volume. 22, Issue 2, 020021(2024)

Current status and development of CMOS SiPM for scintillator-based radiation detectors toward all-digital sensors [Invited]

Nicola D’Ascenzo^1,2、*, Wentao Hu^1,2, Hui Lao³, Yuexuan Hua³, Bo Zhang^1,4, Lei Fang^1,4, Daoming Xi⁵, Rui Zheng⁶, Ao Qiu^1,2, Emanuele Antonecchia^1,2, Yiqing Ling^1,2, Yuqing Liu⁶, Yan Li⁷, Hang Yu⁷, Peng Xiao^1,2, and Qingguo Xie^1,2、**

Author Affiliations

¹Wuhan National Laboratory for Optoelectronics, Wuhan 430074, China

²Biomedical Engineering Department, Huazhong University of Science and Technology, Wuhan 430074, China

³RAYQUANT Technology Co., Ltd., Ezhou 436044, China

⁴RAYSOLUTION Healthcare Co., Ltd., Hefei 230000, China

⁵RAYMEASURE Technology Co., Ltd., Suzhou 215000, China

⁶RAYCAN Technology Co., Ltd., Suzhou 215000, China

⁷College of Computer Science and Software Engineering, Shenzhen University, Shenzhen 518060, China

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References(78)

[1] D. J. Herbert, V. Saveliev, N. Belcari et al. First results of scintillator readout with silicon photomultiplier. IEEE Trans. Nuc. Sci., 53, 389(2006).

[2] M. Bisogni, A. Del Guerra, N. Belcari. Medical applications of silicon photomultipliers. Nucl. Instrum. Met. Phys. Res. A, 926, 118(2019).

[3] N. D’Ascenzo, E. Antonecchia, A. Brensing et al. A novel high photon detection efficiency silicon photomultiplier with shallow junction in 0.35 µm CMOS. IEEE Elecron. Dev. Lett., 40, 1471(2019).

[4] .

[5] .

[6] .

[7] F. Loignon-Houle, S. Gundacker, M. Toussaint et al. DOI estimation through signal arrival time distribution: a theoretical description including proof of concept measurements. Phys. Med. Biol., 66, 095015(2021).

[8] F. Gramuglia, A. Muntean, C. Fenoglio et al. Architecture and characterization of a CMOS 3D-stacked FSI multi-channel digital SiPM for time-of-flight PET applications. IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC)(2021).

[9] S. Mandai, E. Charbon. Multi-channel digital SiPMs: concept, analysis and implementation. IEEE Nuclear Science Symposium and Medical Imaging Conference Record, 1840(2008).

[10] A. Carimatto, S. Mandai, E. Venialgo et al. 11.4 A 67,392-SPAD PVTB-compensated multi-channel digital SiPM with 432 column-parallel 48 ps 17b TDCs for endoscopic time-of-flight PET. IEEE International Solid-State Circuits Conference-(ISSCC) Digest of Technical Papers, 1(2015).

[11] L. H. C. Braga, L. Gasparini, L. Grant et al. A fully digital 8 × 16 SiPM array for PET applications with per-pixel TDCs and real-time energy output. IEEE J. Solid-State Circ., 49, 301(2014).

[12] X. Liang, N. D’Ascenzo, W. Brockherde et al. Silicon photomultipliers with area up to 9 mm2 in a 0.35-µm CMOS process. IEEE J. Elecron. Dev. Soc., 7, 239(2019).

[13] N. D’Ascenzo, V. Saveliev. Study of silicon photomultipliers for the medical imaging systems. Nucl. Instrum. Meth. Phys. Res. A, 695, 265(2012).

[14] Q. Xie, C. Kao, Z. Hsiau et al. A new approach for pulse processing in positron emission tomography. IEEE Trans. Nuc. Sci., 52, 988(2005).

[15] S. R. Cherry, J. A. Sorenson, M. E. Phelps. Physics in Nuclear Medicine(2012).

[16] S. Gundacker, G. Borghi, S. Cherry et al. On timing-optimized SiPMs for Cherenkov detection to boost low cost time-of-flight PET. Phys. Med. Biol., 68, 165016(2023).

[17] E. Roncalli, M. Mosleh-Shirazi, A. Badano. Modelling the transport of optical photons in scintillation detectors for diagnostic and radiotherapy imaging. Phys. Med. Biol., 62, R207(2017).

[18] F. Müller, D. Schug, P. Hallen et al. Gradient tree boosting-based positioning method for monolithic scintillator crystals in positron emission tomography. IEEE Trans. Rad. Plasm. Med. Sci., 2, 411(2018).

[19] H. T. Van Dam, G. Borghi, S. Seifert et al. Sub-200 ps CRT in monolithic scintillator PET detectors using digital SiPM arrays and maximum likelihood interaction time estimation. Phys. Med. Biol., 58, 3243(2013).

[20] W. Ha, E. Park, B. Park et al. Noise optimization of single-photon avalanche diodes fabricated in 110 nm CMOS image sensor technology. Opt. Express, 30, 14958(2022).

[21] G. Ambrosi, M. Ambrosio, C. Aeamo et al. High-density near-ultraviolet silicon photomultipliers: characterization of photosensors for Cherenkov light detection. Nucl. Instrum. Methods Phys. Res. A, 1049, 168023(2023).

[22] C. Niclass, A. Rochas, P.-A. Besse et al. Toward a 3-D camera based on single photon avalanche diodes. IEEE J. Sel. Top. Quantum Electron., 10, 796(2004).

[23] A. Rochas, M. Gosch, A. Serov et al. First fully integrated 2-D array of single-photon detectors in standard CMPS technology. IEEE Photon. Technol. Lett., 15, 963(2003).

[24] S. Tisa, F. Zappa, I. Labanca. On-chip detection and counting of single-photons. IEEE InternationalElectron Devices Meeting, 815(2005).

[25] D. Stoppa, L. Pancheri, M. Scandiuzzo et al. A CMOS 3-D imager based on single photon avalanche diode. IEEE Trans. Circ. Syst., 54, 4(2007).

[26] C. Niclass, A. Rochas, P. A. Besse et al. Design and characterization of a CMOS 3-D image sensor based on single photon avalanche diodes. IEEE J. Solid-State Circ., 40, 1847(2005).

[27] D. Stoppa, L. Pancheri, M. Scandiuzzo et al. A single-photon-avalanche-diode 3D imager. Proceedings of the 31st European Solid-State Circuits Conference(2005).

[28] A. Rochas, M. Gani, B. Furrer et al. Single photon detector fabricated in a complementary metal-oxide-semiconductor high-voltage technology. Rev. Sci. Instrum., 74, 3263(2003).

[29] M. Shawkat, N. Mcfarlane. A digital CMOS silicon photomultiplier using perimeter gated single photon avalanche diodes with asynchronous AER readout. IEEE Trans. Circ. Syst. Regul. Pap., 67, 4818(2020).

[30] L. Pancheri, D. Stoppa. Low-noise CMOS single-photon avalanche diodes with 32 ns dead time. ESSDERC 2007-37th European Solid State Device Research Conference(2007).

[31] M. H. U. Habib, N. McFarlane. A perimeter gated single photon avalanche diode based silicon photomultiplier as optical detector. IEEE 58th International Midwest Symposium on Circuits and Systems (MWSCAS)(2015).

[32] K. Jradi, D. Pellion, D. Ginhac. Design, characterization and analysis of a 0.35 µm CMOS SPAD. Sensors, 14, 22773(2014).

[33] E. Vilella, A. Diéguez. A gated single-photon avalanche diode array fabricated in a conventional CMOS process for triggered systems. Sens. Actuators A, 186, 163(2012).

[34] E. Vilella, O. Alonso, A. Montiel et al. A low-noise time-gated single-photon detector in a HV-CMOS technology for triggered imaging. Sens. Actuator A, 201, 342(2013).

[35] A. Arbat, A. Comerma, J. Trenado et al. High voltage vs. high integration: a comparison between CMOS technologies for SPAD cameras. Proc. SPIE, 7780, 77801G(2010).

[36] D. Stoppa, D. Mosconi, L. Pancheri et al. Single-photon avalanche diode CMOS sensor for time-resolved fluorescence measurements. IEEE Sens. J., 9, 1084(2009).

[37] C. Niclass, C. Favi, T. Kluter et al. Single-photon synchronous detection. IEEE J. Solid-State Circ., 44, 1977(2009).

[38] S. Tisa, F. Guerrieri, A. Tosi et al. 100 kframe/s 8 bit monolithic single- photon imagers. ESSDERC 2008-38th European Solid-State Device Research Conference(2008).

[39] S. Tisa, F. Guerrieri, F. Zappa. Variable load quenching circuit for single photon avalanche diodes. Opt. Express, 16, 2232(2008).

[40] C. Niclass, C. Favi, T. Kluter et al. A 128 × 128 single-photon image sensor with column-level 10-bit time-to-digital converter array. IEEE J. Solid-State Circ., 43, 2977(2008).

[41] C. Niclass, M. Sergio, E. Charbon. A single photon avalanche diode array fabricated in 0.35 µm CMOS and based on an event-driven readout for TCSPC experiments. Proc. SPIE, 6372, 63720S(2006).

[42] H. Finkelstein, M. J. Hsu, S. C. Esener. Sti-bounded single-photon avalanche diode in a deep-submicrometer CMOS technology. IEEE Electron Dev. Lett., 27, 887(2006).

[43] N. Faramarzpour, M. J. Deen, S. Shirani et al. Fully integrated single photon avalanche diode detector in standard CMOS 0.18-µm technology. IEEE Trans. Electron Dev., 55, 760(2008).

[44] L. D. Huang, J. Y. Wu, J. P. Wang et al. Single-photon avalanche diodes in 0.18-µm high-voltage CMOS technology. Opt. Express, 25, 13333(2017).

[45] L. Pancheri, D. Stoppa. Low-noise single photon avalanche diodes in 0.15-µm CMOS technology. Proceedings of the European Solid-State Device Research Conference (ESSDERC)(2011).

[46] J. A. Richardson, L. A. Grant, R. K. Henderson. Low dark count single-photon avalanche diode structure compatible with standard nanometer scale CMOS technology. IEEE Photon. Technol. Lett., 21, 1020(2009).

[47] M. Gersbach, Y. Maruyama, R. Trimananda et al. A time-resolved, low-noise single-photon image sensor fabricated in deep-submicron CMOS technology. IEEE J. Solid-State Circ., 47, 1394(2012).

[48] R. Henderson, L. A. Grant. Reduction of band-to-band tunneling in deep-submicron cmos single photon avalanche photodiodes. International Image Sensor Workshop, 26(2009).

[49] C. Niclass, M. Gersbach, R. Henderson et al. A single photon avalanche diode implemented in 130-nm CMOS technology. IEEE J. Sel. Top. Quantum Electron., 13, 863(2007).

[50] A. Arbat. Towards a forward tracker detector based on geiger mode avalanche photodiodes for future linear colliders(2010).

[51] E. Vilella, O. Alonso, A. Dieguez. 3D integration of geiger-mode avalanche photodiodes aimed to very high fill-factor pixels for future linear colliders. Nucl. Instrum. Methods Phys. Res. A, 731, 103(2013).

[52] A. Eshkoli, Y. Nemirovsky. Characterization and architecture of monolithic N+P-CMOS-SiPM array for ToF measurements. IEEE Trans. Instrum. Meas., 70, 2002909(2020).

[53] D. Shin, B. Park, Y. Chae et al. The effect of a deep virtual guard ring on the device characteristics of silicon single photon avalanche diodes. IEEE Trans. Electron Dev., 66, 2986(2019).

[54] M. A. Karami, M. Gersbach, H.-J. Yoon et al. A new single-photon avalanche diode in 90 nm standard CMOS technology. Opt. Express, 18, 22158(2010).

[55] E. A. Webster, J. A. Richardson, L. A. Grant et al. A single-photon avalanche diode in 90-nm CMOS imaging technology with 44% photon detection efficiency at 690 nm. IEEE Electron Dev. Lett., 33, 694(2012).

[56] W. Ha, E. Park, D. Eom et al. Single-photon avalanche diode fabricated in standard 55 nm bipolar-CMOS-DMOS technology with sub-20 V breakdown voltage. Opt. Express, 31, 13798(2023).

[57] J. Zhao, T. Milanese, F. Gramuglia et al. On analog silicon photomultipliers in standard 55-nm BCD technology for LiDAR applications. IEEE J. Sel. Top. Quantum Electron., 28, C1(2022).

[58] E. Park, W. Ha, H. Park et al. A back-illuminated SPAD fabricated with 40 nm CMOS image sensor technology achieving near 40% PDP at 940 nm. IEEE J. Sel. Top. Quantum Electron., 30, 3800207(2024).

[59] N. D’Ascenzo, Q. Xie. Possible layout solutions for the improvement of the dark rate of geiger mode avalanche structures in the GLOBALFOUNDRIES BCDLITE 0.18 µm CMOS technology. J. Instrum., 13, T04007(2018).

[60] N. D’Ascenzo, X. Zhang, Q. Xie. Application of CMOS technology to silicon photomultiplier sensors. Sensors, 17, 2204(2017).

[61] N. D’Ascenzo, W. Brockherde, S. Dreiner et al. Design and characterization of a silicon photomultiplier in 0.35-µm CMOS. IEEE J. Elec. Dev. Soc., 6, 74(2018).

[62] F. Villa, D. Bronzi, M. Vergani et al. Analog SiPM in planar CMOS technology. 44th European Solid State Device Research Conference (ESSDERC), 294(2014).

[63] M. Sanzaro, F. Signorelli, P. Gattari et al. 0.16 µm–BCD silicon photomultipliers with sharp timing response and reduced correlated noise. Sensors, 18, 3763(2018).

[64] K. Shimazoe, C. Kim, H. Takahashi et al. Design improvement and characterization of SOI-based silicon-photomultiplier prototype. Nucl. Instrum. Methods Phys. Res. Sect. A, 1047, 167902(2022).

[65] M. Liu, B. Liu, J. Hu et al. A 16-channel analog CMOS SiPM with on-chip front-end for D-ToF LiDAR. IEEE Trans. Circuits Syst., 69, 2376(2022).

[66] M. S. A. Shawkat, M. H. U. Habib, N. McFarlane. An analog CMOS silicon photomultiplier using perimeter-gated single-photon avalanche diodes. IEEE Trans. Circuits Syst., 65, 3830(2018).

[67] N. D’Ascenzo, L. Wang, X. Zhang et al. The JOINBON SiPM for the readout of LySO crystals: a multi voltage threshold approach. J. Instrum., 15, C07006(2020).

[68] S. Gundacker, R. Turtos, N. Kratochwil et al. Experimental time resolution limits of modern SiPMs and TOF-PET detectors exploring different scintillators and Cherenkov emission. Phys. Med. Biol., 65, 025001(2020).

[69] T. Frach, G. Prescher, C. Degenhardt et al. The digital silicon photomultiplier—principle of operation and intrinsic detector performance. Proceedings of the IEEE Nuclear Science Symposium Conference Record, 1959(2009).

[70] M. Streun. PhenoPET: a dedicated PET scanner for plant research based on digital SiPMs (DPCs). IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC), 1(2014).

[71] P. Lopes, J. Bauer, A. Salomon et al. First in situ TOF-PET study using digital photon counters for proton range verification. Phys. Med. Biol., 61, 6203(2016).

[72] J. F. Pratte, F. Nolet, S. Parent et al. 3D photon-to-digital converter for radiation instrumentation: motivation and future works. Sensors, 21, 598(2021).

[73] B. Aull, E. Duerr, J. Frechette et al. Large-format geiger-mode avalanche photodiode arrays and readout circuits. IEEE J. Sel. Top. Quant. Electron., 24, 3800510(2018).

[74] T. Mizuno, H. Ikeda, T. Nagano et al. Three-dimensional image sensor with MPPC for flash LIDAR. Trans. Jap. Soc. Aeron. Space Sci., 63, 42(2020).

[75] A. Ximenes, P. Padmanabhan, M. Lee et al. A modular, direct time-of-flight depth sensor in 45/65-nm 3-D-stacked CMOS technology. IEEE J. Solid State Circ., 54, 3203(2019).

[76] S. Hutchings, N. Johnston, I. Gyongy et al. A reconfigurable 3-D-stacked SPAD imager with in-pixel histogramming for flash LIDAR or high-speed time-of-flight imaging. IEEE J. Solid State Circ., 54, 2947(2019).

[77] E. Conca, V. Sesta, M. Buttafava et al. Large-area, fast-gated digital SiPM with integrated TDC for portable and wearable time-domain NIRS. IEEE J. Solid State Circ., 55, 3097(2020).

[78] N. D’Ascenzo, V. Saveliev, L. Wang et al. A digital photomultiplier device.

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Nicola D’Ascenzo, Wentao Hu, Hui Lao, Yuexuan Hua, Bo Zhang, Lei Fang, Daoming Xi, Rui Zheng, Ao Qiu, Emanuele Antonecchia, Yiqing Ling, Yuqing Liu, Yan Li, Hang Yu, Peng Xiao, Qingguo Xie, "Current status and development of CMOS SiPM for scintillator-based radiation detectors toward all-digital sensors [Invited]," Chin. Opt. Lett. 22, 020021 (2024)

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