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Published January 1, 2023 | public
Journal Article Metadata-only

Investigation of signal characteristics and charge sharing in AC-LGADs with laser and test beam measurements

Ott, Jennifer ORCID icon
Letts, Sean
Molnar, Adam ORCID icon
Ryan, Eric ORCID icon
Wong, Marcus ORCID icon
Mazza, Simone M. ORCID icon
Nizam, Mohammad ORCID icon
Sadrozinski, Hartmut F.-W. ORCID icon
Schumm, Bruce ORCID icon
Seiden, Abraham ORCID icon
Shin, K.-W. Taylor ORCID icon
Heller, Ryan ORCID icon
Madrid, Christopher ORCID icon
Apresyan, Artur ORCID icon
Brooks, William K.
Chen, Wei ORCID icon
D'Amen, Gabriele ORCID icon
Giacomini, Gabriele
Goya, Ikumi
Hara, Kazuhiko ORCID icon
Kita, Sayuka ORCID icon
Los, Sergey ORCID icon
Nakamura, Koji ORCID icon
Peña, Cristián ORCID icon
San Martin, Claudio
Ueda, Tatsuki
Tricoli, Alessandro ORCID icon
Xie, Si ORCID icon

Abstract

AC-LGADs, also referred to as resistive silicon detectors, are a recent development of low-gain avalanche detectors (LGADs), based on a sensor design where the multiplication layer and n⁺ contact are continuous, and only the metal layer is patterned. In AC-LGADs, the signal is capacitively coupled from the continuous, resistive n⁺ layer over a dielectric to the metal electrodes. Therefore, the spatial resolution is not only influenced by the electrode pitch, but also the relative size of the metal electrodes. Signal propagation between the metallized areas and charge sharing between electrodes plays a larger role in these detectors than in conventional silicon sensors read out in DC mode. AC-LGADs from two manufacturers were studied in beam tests and with infrared laser scans. The impact of n⁺ layer resistivity and metal electrode pitch on the charge sharing and achievable position resolution is shown. For strips with 100 µm pitch, a resolution of ¡ 5 µm can be reached. The charge sharing between neighboring strips is investigated in more detail, indicating the induction of signal charge and subsequent re-sharing over the n⁺ layer. Furthermore, an approach to identify signal sharing over large distances is presented.

Additional Information

We thank the Fermilab accelerator and FTBF personnel for the excellent performance of the accelerator and support of the test beam facility, in particular M. Kiburg, E. Niner and E. Schmidt. We also thank the SiDet department for preparing the readout boards by mounting and wirebonding the AC-LGAD sensors. Finally, we thank L. Uplegger for developing the telescope tracker and a large part of the DAQ system. This study was conducted using the resources of the Fermi National Accelerator Laboratory (Fermilab), a U.S. Department of Energy, Office of Science, HEP User Facility. Fermilab is managed by the Fermi Research Alliance, LLC (FRA), acting under Contract No. DE-AC02-07CH11359. This research is partially funded by the U.S.-Japan Science and Technology Cooperation Program in High Energy Physics, through Department of Energy under FWP 20-32 in the USA, and via High Energy Accelerator Research Organization (KEK) in Japan. This work was also supported by the U.S. Department of Energy under grant DE-SC0010107-005; used resources of the Center for Functional Nanomaterials, which is a U.S. DOE Office of Science Facility, at Brookhaven National Laboratory under Contract No. DE-SC0012704; and was supported by the Chilean ANID PIA/APOYO AFB180002 and ANID - Millennium Science Initiative Program - ICN2019-044. This research was partially supported by Grant-in-Aid for scientific research on advanced basic research (Grant No. 19H05193, 19H04393, 21H0073 and 21H01099) from the Ministry of Education, Culture, Sports, Science and Technology, of Japan. J. Ott would like to acknowledge funding from the Finnish Cultural Foundation through the Postdoc Pool of Finnish Foundations.

Additional details

Identifiers Funding Dates
Created:
August 22, 2023
Modified:
October 24, 2023