Your search keyword '"Boscardin, M"' showing total 765 results

1. Plasma-Based Etching Approach for GEM Detector Microfabrication at FBK for X-ray polarimetry in space

Author

Lega, A., Novel, D., Facchinelli, T., Sgro', C., Baldini, L., Minuti, M., Boscardin, M., Pepponi, G., Iuppa, R., Hall-Wilton, R., and Latronico, L.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Gas Electron Multiplier (GEM) detectors are crucial for enabling high-resolution X-ray polarisation of astrophysical sources when coupled to custom pixel readout ASIC in Gas Pixel Detectors (GPD), as in the Imaging X-ray Polarimetry Explorer (IXPE), the Polarlight cubesat pathfinder and the PFA telescope onboard the future large enhanced X-ray Timing and Polarimetry (eXTP) Chinese mission. The R&D efforts of the IXPE collaboration have resulted in mature GPD technology. However, limitations in the classical wet-etch or laser-drilled fabrication process of GEMs motivated our exploration of alternative methods. This work focuses on investigating a plasma-based etching approach for fabricating GEM patterns at Fondazione Bruno Kessler (FBK). The objective is to improve the aspect ratio of the GEM holes, to mitigate the charging of the GEM dielectric which generates rate-dependent gain changes. Unlike the traditional wet-etch process, Reactive Ion Etching (RIE) enables more vertical etching profiles and thus better aspect ratios. Moreover, the RIE process promises to overcome non-uniformities in the GEM hole patterns which are believed to cause systemic effects in the azimuthal response of GPDs equipped with either laser-drilled or wet-etch GEMs. We present a GEM geometry with 20 micrometers in diameter and 50 micrometers pitch, accompanied by extensive characterisation (SEM and PFIB) of the structural features and aspect ratios. The collaboration with INFN Pisa and Turin enabled us to compare the electrical properties of these detectors and test their performance in their use as electron multipliers in GPDs. Although this R&D work is in its initial stages, it holds promise for enhancing the sensitivity of the IXPE mission in X-ray polarimetry measurements through GEM pattern with more vertical hole profiles., Comment: IPRD2023 conference

Published

2023

2. High-Precision 4D Tracking with Large Pixels using Thin Resistive Silicon Detectors

Author

Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Costa, M., Betta, G-F. Dalla, Ferrero, M., Ficorella, F., Gioachin, G., Lanteri, L., Mandurrino, M., Menzio, L., Mulargia, R., Pancheri, L., Paternoster, G., Rojas, A., Sadrozinski, H-F W., Seiden, A., Siviero, F., Sola, V., and Tornago, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The basic principle of operation of silicon sensors with resistive read-out is built-in charge sharing. Resistive Silicon Detectors (RSD, also known as AC-LGAD), exploiting the signals seen on the electrodes surrounding the impact point, achieve excellent space and time resolutions even with very large pixels. In this paper, a TCT system using a 1064 nm picosecond laser is used to characterize sensors from the second RSD production at the Fondazione Bruno Kessler. The paper first introduces the parametrization of the errors in the determination of the position and time coordinates in RSD, then outlines the reconstruction method, and finally presents the results. Three different pixel sizes are used in the analysis: 200 x 340, 450 x 450, and 1300 x 1300 microns^2. At gain = 30, the 450 x 450 microns^2 pixel achieves a time jitter of 20 ps and a spatial resolution of 15 microns concurrently, while the 1300 x 1300 microns^2 pixel achieves 30 ps and 30 micron, respectively. The implementation of cross-shaped electrodes improves considerably the response uniformity over the pixel surface., Comment: 28 pages, 23 figures submitted to NIMA

Published

2022

3. Quality Control (QC) of FBK Preproduction 3D Si Sensors for ATLAS HL-LHC Upgrades

Author

Sultan, D M S, Samy, Md Arif Abdulla, Ye, J. X., Boscardin, M., Ficorella, F., Ronchin, S., and Betta, G. -F. Dalla

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The challenging demands of the ATLAS High Luminosity (HL-LHC) Upgrade aim for a complete swap of new generation sensors that should cope with the ultimate radiation hardness. FBK has been one of the prime foundries to develop and fabricate such radiation-hard 3D silicon (Si) sensors. These sensors are chosen to be deployed into the innermost layer of the ATLAS Inner Tracker (ITk). Recently, a pre-production batch of 3D Si sensors of 50x50 um2 pixel geometry, compatible with the full-size ITKPix (RD53B) readout chip, was fabricated. Two wafers holding temporary metal were diced at IZM, Germany, and a systematic QC test campaign was carried out at the University of Trento electronics laboratory. The paper briefly describes the 3D Si sensor design for ATLAS ITk and the required QC characterization setups. It comprises electrical tests (i.e., I-V, C-V, and I-T) of non-irradiated RD53B sensors. In addition, the study of several parametric analyses, i.e., oxide charge density, oxide thickness, inter-pixel resistance, inter-pixel capacitance, etc., are reported with the aid of Process Control Monitor (PCM) structures., Comment: 8 pages, prepared for iWoRiD 2022 Proceeding

Published

2022

4. Solid State Detectors and Tracking for Snowmass

Author

Affolder, A., Apresyan, A., Worm, S., Albrow, M., Ally, D., Ambrose, D., Anderssen, E., Apadula, N., Asenov, P., Armstrong, W., Artuso, M., Barbier, A., Barletta, P., Bauerdick, L., Berry, D., Bomben, M., Boscardin, M., Brau, J., Brooks, W., Breidenbach, M., Buckley, J., Cairo, V., Caputo, R., Carpenter, L., Centis-Vignali, M., Cerullo, M., Collu, A., Chlebana, F., Dalla-Betta, G. -F., Demarteau, M., Deptuch, G., Di Petrillo, K., D'Amen, G., Dragone, A., Fourches, N. T., Garcia-Sciveres, M., Giacomini, G., Gingu, C., Graf, N., Grace, C., Griso, S., Greiner, L., Haber, C., Haller, G., Harris, K., Heim, T., Heinz, U., Heller, R., Hedges, M. T., Herbst, R., Hoeferkamp, M. R., Holmes, T., Holland, S. E., Hsu, S. -C., Islam, R., Jadhav, M., Jindariani, S., Joosten, S., Jung, A., Karmarkar, S., Kenney, C., Kierans, C., Kim, J., Kim, S., Klein, S., Koshy, A., Krizka, K., Lai, A., Lee, L., Linssen, L., Lipton, R., Liu, T., Madrid, C., Mahajan, T., Markiewicz, T., Markovic, B., Mazza, S., Mazziotta, M., Mei, Y., Merkel, P., Metcalfe, J., Meziani, Z. -E., Minns, A., Moscatelli, F., Murat, P., Muth, J., Nachman, B., Nahn, S., Narain, M., Narayanan, E. A., Nelson, T., Nielsen, J., Oktyabrsky, S., Ott, J., Palomo, F. R., Passeri, D., Patti, R., Peltola, T., Pena, C., Peng, C., Renard, C., Reimer, P., Rogan, C., Rota, L., Sadrozinski, H., Segal, J., Schwartzman, A., Schumm, B., Scott, M., Seidel, S., Seiden, A., Sekely, B., Shi, X., Sichtermann, E., Sinev, N., Sonneveld, J., Spiegel, L., Steinhebel, A., Strom, D., Sultan, D. M. S., Sumant, A., Tokranov, V., Tricoli, A., Trischuk, W., Tumasyan, A., Uplegger, L., Vernieri, C., Wang, H., Wagenknecht, P., Weber, H., Xie, S., Yakimov, M., Ye, Z., Young, C., and Zurek, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Tracking detectors are of vital importance for collider-based high energy physics (HEP) experiments. The primary purpose of tracking detectors is the precise reconstruction of charged particle trajectories and the reconstruction of secondary vertices. The performance requirements from the community posed by the future collider experiments require an evolution of tracking systems, necessitating the development of new techniques, materials and technologies in order to fully exploit their physics potential. In this article we summarize the discussions and conclusions of the 2022 Snowmass Instrumentation Frontier subgroup on Solid State and Tracking Detectors (Snowmass IF03)., Comment: for the Snowmass Instrumentation Frontier Solid State Detector and Tracking community

Published

2022

5. Beam test results of 25 $\mu$m and 35 $\mu$m thick FBK UFSD]{Beam test results of 25 $\mu$m and 35 $\mu$m thick FBK ultra fast silicon detectors

Author

Carnesecchi, F., Strazzi, S., Alici, A., Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Cavazza, D., Betta, G. -F. Dalla, Durando, S., Ferrero, M., Ficorella, F., Ali, O. Hammad, Mandurrino, M., Margotti, A., Menzio, L., Nania, R., Pancheri, L., Paternoster, G., Scioli, G., Siviero, F., Sola, V., Tornago, M., and Vignola, G.

Subjects

Physics - Instrumentation and Detectors

Abstract

This paper presents the measurements on first very thin Ultra Fast Silicon Detectors (UFSDs) produced by Fondazione Bruno Kessler; the data have been collected in a beam test setup at the CERN PS, using beam with a momentum of 12 GeV/c. UFSDs with a nominal thickness of 25 $\mu$m and 35 $\mu$m and an area of 1 $\times$ 1 $\text{mm}^2$ have been considered, together with an additional HPK 50-$\mu$m thick sensor, taken as reference. Their timing performances have been studied as a function of the applied voltage and gain. A time resolution of about 25 ps and of 22 ps at a voltage of 120 V and 240 V has been obtained for the 25 and 35 $\mu$m thick UFSDs, respectively.

Published

2022

6. DC-coupled resistive silicon detectors for 4-D tracking

Author

Menzio, L., Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Costa, M., Betta, G-F. Dalla, Ferrero, M., Ficorella, F., Gioachin, G., Mandurrino, M., Pancheri, L., Paternoster, G., Siviero, F., Sola, V., and Tornago, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Physics - Computational Physics

Abstract

In this work, we introduce a new design concept: the DC-Coupled Resistive Silicon Detectors, based on the LGAD technology. This new approach intends to address a few known features of the first generation of AC-Coupled Resistive Silicon Detectors (RSD). Our simulation exploits a fast hybrid approach based on a combination of two packages, Weightfield2 and LTSpice. It demonstrates that the key features of the RSD design are maintained, yielding excellent timing and spatial resolutions: a few tens of ps and a few microns. In the presentation, we will outline the optimization methodology and the results of the simulation. We will present detailed studies on the effect of changing the ratio between the n+ layer resistivity and the low-resistivity ring and on the achievable temporal and spatial resolution.

Published

2022

7. Performance of 3D trench silicon pixel sensors irradiated up to [formula omitted]

Author

Lampis, A., Addison, M., Bellora, A., Boscardin, M., Brundu, D., Cardini, A., Cossu, G.M., Dalla Betta, G.F., La Delfa, L., Lai, A., Loi, A., Obertino, M., Ronchin, S., Vecchi, S., and Verdoglia, M.

Published

2024

8. Thin silicon sensors for extreme fluences: A doping compensation strategy

Author

Morozzi, A., Fondacci, A., Croci, T., Arcidiacono, R., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Ferrero, M., Lanteri, L., Menzio, L., Paternoster, G., Siviero, F., White, R., Moscatelli, F., Passeri, D., and Sola, V.

Published

2024

9. Measurements and TCAD simulations of guard-ring structures of thin silicon sensors before and after irradiation

Author

Croci, T., Fondacci, A., White, R., Durando, M., Galletto, S., Borghi, G., Paternoster, G., Vignali, M. Centis, Boscardin, M., Arcidiacono, R., Cartiglia, N., Moscatelli, F., Passeri, D., Ferrero, M., Sola, V., and Morozzi, A.

Published

2024

10. TCAD investigation of Compensated LGAD Sensors for extreme fluence

Author

Fondacci, A., Croci, T., Passeri, D., Morozzi, A., White, R., Siviero, F., Menzio, L., Lanteri, L., Ferrero, M., Arcidiacono, R., Cartiglia, N., Boscardin, M., Centis Vignali, M., Paternoster, G., Sola, V., and Moscatelli, F.

Published

2024

11. Novel Sensors for Particle Tracking: a Contribution to the Snowmass Community Planning Exercise of 2021

Author

Hoeferkamp, M. R., Seidel, S., Kim, S., Metcalfe, J., Sumant, A., Kagan, H., Trischuk, W., Boscardin, M., Betta, G. -F. Dalla, Sultan, D. M. S., Fourches, N. T., Renard, C., Barbier, A., Mahajan, T., Minns, A., Tokranov, V., Yakimov, M., Oktyabrsky, S., Gingu, C., Murat, P., and Hedges, M. T.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Five contemporary technologies are discussed in the context of their potential roles in particle tracking for future high energy physics applications. These include sensors of the 3D configuration, in both diamond and silicon, submicron-dimension pixels, thin film detectors, and scintillating quantum dots in gallium arsenide. Drivers of the technologies include radiation hardness, excellent position, vertex, and timing resolution, simplified integration, and optimized power, cost, and material., Comment: 15 pages, 6 figures

Published

2022

12. Tuning of gain layer doping concentration and Carbon implantation effect on deep gain layer

Author

Mazza, S. M., Gee, C., Zhao, Y., Padilla, R., Ryan, E., Tournebise, N., Darby, B., McKinney-Martinez, F., Sadrozinski, H. F. -W., Seiden, A., Schumm, B., Cindro, V., Kramberger, G., Mandić, I., Mikuž, M., Zavrtanik, M., Arcidiacono, R., Cartiglia, N., Ferrero, M., Mandurrino, M., Sola, V., Staiano, A., Boscardin, M., Della Betta, G. F., Ficorella, F., Pancheri, L., and Paternoster, G.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Next generation Low Gain Avalanche Diodes (LGAD) produced by Hamamatsu photonics (HPK) and Fondazione Bruno Kessler (FBK) were tested before and after irradiation with ~1MeV neutrons at the JSI facility in Ljubljana. Sensors were irradiated to a maximum 1-MeV equivalent fluence of 2.5E15 Neq/cm2. The sensors analysed in this paper are an improvement after the lessons learned from previous FBK and HPK productions that were already reported in precedent papers. The gain layer of HPK sensors was fine-tuned to optimize the performance before and after irradiation. FBK sensors instead combined the benefit of Carbon infusion and deep gain layer to further the radiation hardness of the sensors and reduced the bulk thickness to enhance the timing resolution. The sensor performance was measured in charge collection studies using \b{eta}-particles from a 90Sr source and in capacitance-voltage scans (C-V) to determine the bias to deplete the gain layer. The collected charge and the timing resolution were measured as a function of bias voltage at -30C. Finally a correlation is shown between the bias voltage to deplete the gain layer and the bias voltage needed to reach a certain amount of gain in the sensor. HPK sensors showed a better performance before irradiation while maintaining the radiation hardness of the previous production. FBK sensors showed exceptional radiation hardness allowing a collected charge up to 10 fC and a time resolution of 40 ps at the maximum fluence., Comment: arXiv admin note: text overlap with arXiv:2004.05260

Published

2022

13. The second production of RSD (AC-LGAD) at FBK

Author

Mandurrino, M., Arcidiacono, R., Bisht, A., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Betta, G. -F. Dalla, Ferrero, M., Ficorella, F., Ali, O. Hammad, Rojas, A. D. Martinez, Menzio, L., Pancheri, L., Paternoster, G., Siviero, F., Sola, V., and Tornago, M.

Subjects

Physics - Instrumentation and Detectors

Abstract

In this contribution we describe the second run of RSD (Resistive AC-Coupled Silicon Detectors) designed at INFN Torino and produced by Fondazione Bruno Kessler (FBK), Trento. RSD are n-in-p detectors intended for 4D particle tracking based on the LGAD technology that get rid of any segmentation implant in order to achieve the 100% fill-factor. They are characterized by three key-elements, (i) a continuous gain implant, (ii) a resistive n-cathode and (iii) a dielectric coupling layer deposited on top, guaranteeing a good spatial reconstruction of the hit position while benefiting from the good timing properties of LGADs. We will start from the very promising results of our RSD1 batch in terms of tracking performances and then we will move to the description of the design of the RSD2 run. In particular, the principles driving the sensor design and the specific AC-electrode layout adopted to optimize the signal confinement will be addressed.

Published

2021

14. Inter-pad dead regions of irradiated FBK Low Gain Avalanche Detectors

Author

Darby, B., Mazza, S. M., McKinney-Martinez, F., Padilla, R., Sadrozinski, H. F. -W., Seiden, A., Schumm, B., Wilder, M., Zhao, Y., Arcidiacono, R., Cartiglia, N., Ferrero, M., Mandurrino, M., Sola, V., Staiano, A., Cindro, V., Kranberger, G., Mandiz, I., Mikuz, M., Zavtranik, M., Boscardin, M., Della Betta, G. F., Ficorella, F., Pancheri, L., and Paternoster, G.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Low Gain Avalanche Detectors (LGADs) are a type of thin silicon detector with a highly doped gain layer. LGADs manufactured by Fondazione Bruno Kessler (FBK) were tested before and after irradiation with neutrons. In this study, the Inter-pad distances (IPDs), defined as the width of the distances between pads, were measured with a TCT laser system. The response of the laser was tuned using $\beta$-particles from a 90Sr source. These insensitive "dead zones" are created by a protection structure to avoid breakdown, the Junction Termination Extension (JTE), which separates the pads. The effect of neutron radiation damage at \fluence{1.5}{15}, and \fluence{2.5}{15} on IPDs was studied. These distances are compared to the nominal distances given from the vendor, it was found that the higher fluence corresponds to a better matching of the nominal IPD.

Published

2021

15. The first batch of compensated LGAD sensors

Author

Sola, V., Paternoster, G., Morozzi, A., Arcidiacono, R., Barozzi, M., Borghi, G., Boscardin, M., Cartiglia, N., Centis Vignali, M., Costa, M., Croci, T., Ferrero, M., Fondacci, A., Ficorella, F., Giordanengo, S., Hammad Ali, O., Hanna, C., Lanteri, L., Menzio, L., Moscatelli, F., Passeri, D., Pastrone, N., Siviero, F., and White, R.S.

Published

2024

16. Measurements and TCAD simulations of innovative RSD and DC-RSD LGAD devices for future 4D tracking

Author

Moscatelli, F., Fondacci, A., Arcidiacono, R., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Croci, T., Ferrero, M., Ali, O. Hammad, Lanteri, L., Losana, A., Menzio, L., Monaco, V., Mulargia, R., Passeri, D., Paternoster, G., Siviero, F., Sola, V., and Morozzi, A.

Published

2024

17. Testing of planar hydrogenated amorphous silicon sensors with charge selective contacts for the construction of 3D- detectors

Author

Menichelli, M., Bizzarri, M., Boscardin, M., Caprai, M., Caricato, A. P., Cirrone, G. A. P., Crivellari, M., Cupparo, I., Cuttone, G., Dunand, S., Fanò, L., Hammad, O., Ionica, M., Kanxheri, K., Large, M., Maruccio, G., Monteduro, A. G., Morozzi, A., Moscatelli, F., Papi, A., Passeri, D., Petasecca, M., Petringa, G., Quarta, G., Rizzato, S., Rossi, A., Rossi, G., Scorzoni, A., Servoli, L., Talamonti, C., Verzellesi, G., and Wyrsch, N.

Subjects

Physics - Instrumentation and Detectors

Abstract

Hydrogenated Amorphous Silicon (a-Si:H) is a material well known for its intrinsic radiation hardness and is primarily utilized in solar cells as well as for particle detection and dosimetry. Planar p-i-n diode detectors are fabricated entirely by means of intrinsic and doped PECVD of a mixture of Silane (SiH4) and molecular Hydrogen. In order to develop 3D detector geometries using a-Si:H, two options for the junction fabrication have been considered: ion implantation and charge selective contacts through atomic layer deposition. In order to test the functionality of the charge selective contact electrodes, planar detectors have been fabricated utilizing this technique. In this paper, we provide a general overview of the 3D fabrication project followed by the results of leakage current measurements and x-ray dosimetric tests performed on planar diodes containing charge selective contacts to investigate the feasibility of the charge selective contact methodology for integration with the proposed 3D detector architectures., Comment: Submitted to JINST

Published

2021

18. Design optimization of the UFSD inter-pad region

Author

Siviero, F., Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Costa, M., Dalla Betta, G.-F., Ferrero, M., Ficorella, F., Mandurrino, M., Markovic, L., Pancheri, L., Paternoster, G., Sola, V., and Tornago, M.

Published

2024

19. Resistive AC-Coupled Silicon Detectors: principles of operation and first results from a combined analysis of beam test and laser data

Author

Tornago, M., Arcidiacono, R., Cartiglia, N., Costa, M., Ferrero, M., Mandurrino, M., Siviero, F., Sola, V., Staiano, A., Apresyan, A., Di Petrillo, K., Heller, R., Los, S., Borghi, G., Boscardin, M., Betta, G-F Dalla, Ficorella, F., Pancheri, L., Paternoster, G., Sadrozinski, H., and Seiden, A.

Subjects

Physics - Instrumentation and Detectors

Abstract

This paper presents the principles of operation of Resistive AC-Coupled Silicon Detectors (RSDs) and measurements of the temporal and spatial resolutions using a combined analysis of laser and beam test data. RSDs are a new type of n-in-p silicon sensor based on the Low-Gain Avalanche Diode (LGAD) technology, where the $n^+$ implant has been designed to be resistive, and the read-out is obtained via AC-coupling. The truly innovative feature of RSD is that the signal generated by an impinging particle is shared isotropically among multiple read-out pads without the need for floating electrodes or an external magnetic field. Careful tuning of the coupling oxide thickness and the $n^+$ doping profile is at the basis of the successful functioning of this device. Several RSD matrices with different pad width-pitch geometries have been extensively tested with a laser setup in the Laboratory for Innovative Silicon Sensors in Torino, while a smaller set of devices have been tested at the Fermilab Test Beam Facility with a 120 GeV/c proton beam. The measured spatial resolution ranges between $2.5\; \mu m$ for 70-100 pad-pitch geometry and $17\; \mu m$ with 200-500 matrices, a factor of 10 better than what is achievable in binary read-out ($bin\; size/ \sqrt{12}$). Beam test data show a temporal resolution of $\sim 40\; ps$ for 200-$\mu m$ pitch devices, in line with the best performances of LGAD sensors at the same gain., Comment: 34 pages, 33 figures

Published

2020

20. A novel hybrid microdosimeter for radiation field characterization based on TEPC detector and LGADs tracker: a feasibility study

Author

Missiaggia, M., Pierobon, E., Castelluzzo, M., Perinelli, A., Cordoni, F., Vignali, M. Centis, Borghi, G., Bellinzona, V. E., Scifoni, E., Tommasino, F., Monaco, V., Ricci, L., Boscardin, \\M., and La Tessa, C.

Subjects

Physics - Instrumentation and Detectors, Physics - Applied Physics, Physics - Biological Physics, Physics - Medical Physics

Abstract

In microdosimetry, lineal energies y are calculated from energy depositions $\epsilon$ inside the microdosimeter divided by the mean chord length, whose value is based on geometrical assumptions on both the detector and the radiation field. This work presents an innovative two-stages hybrid detector (HDM: hybrid detector for microdosimetry) composed by a Tissue Equivalent Proportional Counter (TEPC) and a silicon tracker made of 4 Low Gain Avalanche Diode (LGAD). This design provides a direct measurement of energy deposition in tissue as well as particles tracking with a submillimeter spatial resolution. The data collected by the detector allow to obtain the real track length traversed by each particle in the TEPC and thus estimates microdosimetry spectra without the mean chord length approximation. Using Geant4 toolkit, we investigated HDM performances in terms of detection and tracking efficiencies when placed in water and exposed to protons and carbon ions in the therapeutic energy range. The results indicate that the mean chord length approximation underestimate particles with short track, which often are characterized by a high energy deposition and thus can be biologically relevant. Tracking efficiency depends on the LGAD configurations: 34 strips sensors have a higher detection efficiency but lower spatial resolution than 71 strips sensors. Further studies will be performed both with Geant4 and experimentally to optimize the detector design on the bases of the radiation field of interest. The main purpose of HDM is to improve the assessment of the radiation biological effectiveness via microdosimetric measurements, exploiting a new definition of the lineal energy ($y_{T}$), defined as the energy deposition $\epsilon$ inside the microdosimeter divided by the real track length of the particle.

Published

2020

21. MEMS Mirror Manufacturing and Testing for Innovative Space Applications

Author

Bagolini, A., Boscardin, M., Dell'Agnello, S., Monache, G. Delle, Emilio, M. Di Paolo, Porcelli, L., Salvatori, L., and Tibuzzi, M.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Instrumentation and Detectors, Physics - Optics

Abstract

In the framework of the GLARE-X (Geodesy via LAser Ranging from spacE X) project, led by INFN and funded for the years 2019-2021, aiming at significantly advance space geodesy, one shows the initial activities carried out in 2019 in order to manufacture and test adaptive mirrors. This specific article deals with manufacturing and surface quality measurements of the passive substrate of 'candidate' MEMS (Micro-Electro-Mechanical Systems) mirrors for MRRs (Modulated RetroReflectors); further publications will show the active components. The project GLARE-X was approved by INFN for the years 2019-2021: it involves several institutions, including, amongst the other, INFN-LNF and FBK. GLARE-X is an innovative R&D activity, whose at large space geodesy goals will concern the following topics: inverse laser ranging (from a laser terminal in space down to a target on a planet), laser ranging for debris removal and iterative orbit correction, development of high-end ToF (Time of Flight) electronics, manufacturing and testing of MRRs for space, and provision of microreflectors for future NEO (Near Earth Orbit) cubesats. This specific article summarizes the manufacturing and surface quality measurements activities performed on the passive substrate of 'candidate' MEMS mirrors, which will be in turn arranged into MRRs. The final active components, to be realized by 2021, will inherit the manufacturing characteristics chosen thanks to the presented (and further) testing campaigns, and will find suitable space application to NEO, Moon, and Mars devices, like, for example, cooperative and active lidar scatterers for laser altimetry and lasercomm support., Comment: 9 pages, 5 figures

Published

2020

22. Silicon Sensors for Future Particle Trackers

Author

Cartiglia, N., Arcidiacono, R., Borghi, G., Boscardin, M., Costa, M., Galloway, Z., Fausti, F., Ferrero, M., Ficorella, F., Mandurrino, M., Mazza, S., Olave, E. J., Paternoster, G., Siviero, F., Sadrozinski, H. F-W., Sola, V., Staiano, A., Seiden, A., Tornago, M., and Zhao, Y.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Several future high-energy physics facilities are currently being planned. The proposed projects include high energy $e^+ e^-$ circular and linear colliders, hadron colliders and muon colliders, while the Electron-Ion Collider (EIC) has already been approved for construction at the Brookhaven National Laboratory. Each proposal has its own advantages and disadvantages in term of readiness, cost, schedule and physics reach, and each proposal requires the design and production of specific new detectors. This paper first presents the performances required to the future silicon tracking systems at the various new facilities, and then it illustrates a few possibilities for the realization of such silicon trackers. The challenges posed by the future facilities require a new family of silicon detectors, where features such as impact ionization, radiation damage saturation, charge sharing, and analog readout are exploited to meet these new demands.

Published

2020

23. High performance picosecond- and micron-level 4D particle tracking with 100% fill-factor Resistive AC-Coupled Silicon Detectors (RSD)

Author

Mandurrino, M., Cartiglia, N., Tornago, M., Ferrero, M., Siviero, F., Paternoster, G., Ficorella, F., Boscardin, M., Pancheri, L., and Betta, G. F. Dalla

Subjects

Physics - Instrumentation and Detectors

Abstract

In this paper we present a complete characterization of the first batch of Resistive AC-Coupled Silicon Detectors, called RSD1, designed at INFN Torino and manufactured by Fondazione Bruno Kessler (FBK) in Trento. With their 100% fill-factor, RSD represent the new enabling technology for high-precision 4D-tracking. Indeed, being based on the well-known charge multiplication mechanism of Low-Gain Avalanche Detectors (LGAD), they benefit from the very good timing performances of such technology together with an unprecedented resolution of the spatial tracking, which allows to reach the micron-level scale in the track reconstruction. This is essentially due to the absence of any segmentation structure between pads (100% fill-factor) and to other two innovative key-features: the first one is a properly doped n+ resistive layer, slowing down the charges just after being multiplied, and the second one is a dielectric layer grown on Silicon, inducing a capacitive coupling on the metal pads deposited on top of the detector. The very good spatial resolution (micron-level) we measured experimentally - higher than the nominal pad pitch - comes from the analogical nature of the readout of signals, whose amplitude attenuates from the pad center to its periphery, while the outstanding results in terms of timing (less than 14 ps, even better than standard LGAD) are due to a combination of very-fine pitch, analogical response and charge multiplication.

Published

2020

24. High-precision 4D tracking with large pixels using thin resistive silicon detectors

Author

Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Centis Vignali, M., Costa, M., Dalla Betta, G-F., Ferrero, M., Ficorella, F., Gioachin, G., Lanteri, L., Mandurrino, M., Menzio, L., Mulargia, R., Pancheri, L., Paternoster, G., Rojas, A., Sadrozinski, H-F.W., Seiden, A., Siviero, F., Sola, V., and Tornago, M.

Published

2023

25. First demonstration of 200, 100, and 50 um pitch Resistive AC-Coupled Silicon Detectors (RSD) with 100% fill-factor for 4D particle tracking

Author

Mandurrino, M., Arcidiacono, R., Boscardin, M., Cartiglia, N., Betta, G. F. Dalla, Ferrero, M., Ficorella, F., Pancheri, L., Paternoster, G., Siviero, F., and Tornago, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

We designed, produced, and tested RSD (Resistive AC-Coupled Silicon Detectors) devices, an evolution of the standard LGAD (Low-Gain Avalanche Diode) technology where a resistive n-type implant and a coupling dielectric layer have been implemented. The first feature works as a resistive sheet, freezing the multiplied charges, while the second one acts as a capacitive coupling for readout pads. We succeeded in the challenging goal of obtaining very fine pitch (50, 100, and 200 um) while maintaining the signal waveforms suitable for high timing and 4D-tracking performances, as in the standard LGAD-based devices.

Published

2019

26. Neutron irradiation of Hydrogenated Amorphous Silicon p-i-n diodes and charge selective contacts detectors

Author

Menichelli, M., Bizzarri, M., Boscardin, M., Calcagnile, L., Caprai, M., Caricato, A.P., Cirrone, G.A.P., Crivellari, M., Cupparo, I., Cuttone, G., Dunand, S., Fanò, L., Gianfelici, B., Hammad, O., Ionica, M., Kanxheri, K., Large, M., Maruccio, G., Monteduro, A.G., Moscatelli, F., Morozzi, A., Papi, A., Passeri, D., Pedio, M., Petasecca, M., Petringa, G., Peverini, F., Quarta, G., Rizzato, S., Rossi, A., Rossi, G., Scorzoni, A., Servoli, L., Talamonti, C., Verzellesi, G., and Wyrsch, N.

Published

2023

27. First Results on 3D Pixel Sensors Interconnected to the RD53A Readout Chip after Irradiation to $1\times$$10^{16}$neq cm$^{-2}$

Author

Meschini, M., Ceccarelli, R., Dinardo, M., Gennai, S., Moroni, L., Zuolo, D., Demaria, L., Monteil, E., Gaioni, L., Messineo, A., Curras, E., Duarte, J., Fernandez, M., Gomez, G., Garcia, A., Gonzalez, J., Silva, E., Vila, I., Betta, G. F. Dalla, Mendicino, R., and Boscardin, M.

Subjects

Physics - Instrumentation and Detectors

Abstract

Results obtained with 3D columnar pixel sensors bump-bonded to the RD53A prototype readout chip are reported. The interconnected modules have been tested in a hadron beam before and after irradiation to a fluence of about $1\times$$10^{16}$neq cm$^{-2}$ (1MeV equivalent neutrons). All presented results are part of the CMS R&D activities in view of the pixel detector upgrade for the High Luminosity phase of the LHC at CERN (HL-LHC). A preliminary analysis of the collected data shows hit detection efficiencies around 97% measured after proton irradiation., Comment: Conference Proceedings of PIXEL2018, 9$^{\text{th}}$ International Workshop on Semiconductor Pixel Detectors for Particles and Imaging, December 10-14, 2018, Academia Sinica, Taipei

Published

2019

28. Performance of Thin Planar \textit{n-on-p} silicon pixels after HL-LHC radiation fluences

Author

Ducourthial, A., Bomben, M., Calderini, G., Camacho, R., D'Eramo, L., Luise, I., Marchiori, G., Boscardin, M., Bosisio, L., Darbo, G., Betta, G. -F. Dalla, Giacomini, G., Meschini, M., Messineo, A., Ronchin, S., and Zorzi, N.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The tracking detector of ATLAS, one of the experiments at the Large Hadron Collider (LHC), will be upgraded in 2024-2026 to cope with the challenging environment conditions of the High Luminosity LHC (HL-LHC). The LPNHE, in collaboration with FBK and INFN, has produced 130~$\mu$m thick $n-on-p$ silicon pixel sensors which can withstand the expected large particle fluences at HL- LHC, while delivering data at high rate with excellent hit efficiency. Such sensors were tested on beam before and after irradiation both at CERN-SPS and at DESY, and their performances are presented in this paper. Beam test data indicate that these detectors are suited for all the layers where planar sensors are foreseen in the future ATLAS tracker: hit-efficiency is greater than 97\% for fluences $\Phi \lesssim 7\times10^{15}\rm{n_{eq}/cm^2}$ and module power consumption is within the specified limits. Moreover, at a fluence $\Phi = 1.3\times10^{16}\rm{n_{eq}/cm^2}$, hit-efficiency is still as high as 88\% and charge collection efficiency is about 30\%., Comment: 24 pages, 14 figures, published version

Published

2018

29. Proprieties of FBK UFSDs after neutron and proton irradiation up to 6*10e15 neq/cm2

Author

Mazza, S. M., Estrada, E., Galloway, Z., Gee, C., Goto, A., Luce, Z., McKinney-Martinez, F., Rodriguez, R., Sadrozinski, H. F. -W., Seiden, A., Smithers, B., Zhao, Y., Cindro, V., Kramberger, G., Mandić, I., Mikuž, M., Arcidiacono, M. Zavrtanik R., Cartiglia, N., Ferrero, M., Mandurrino, M., Sola, V., Staiano, A., Boscardin, M., Della Betta, G. F., Ficorella, F., Pancheri, L., and Paternoster, G.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The properties of 60-{\mu}m thick Ultra-Fast Silicon Detectors (UFSD) detectors manufactured by Fondazione Bruno Kessler (FBK), Trento (Italy) were tested before and after irradiation with minimum ionizing particles (MIPs) from a 90Sr \b{eta}-source . This FBK production, called UFSD2, has UFSDs with gain layer made of Boron, Boron low-diffusion, Gallium, Carbonated Boron and Carbonated. The irradiation with neutrons took place at the TRIGA reactor in Ljubljana, while the proton irradiation took place at CERN SPS. The sensors were exposed to a neutron fluence of 4*10e14, 8*1014, 1.5*10e15, 3*10e15, 6*10e15 neq/cm2 and to a proton fluence of 9.6*10e14 p/cm2, equivalent to a fluence of 6*10e14 neq/cm2. The internal gain and the timing resolution were measured as a function of bias voltage at -20C. The timing resolution was extracted from the time difference with a second calibrated UFSD in coincidence, using the constant fraction method for both., Comment: arXiv admin note: text overlap with arXiv:1803.02690

Published

2018

30. First FBK Production of 50$\mu$m Ultra-Fast Silicon Detectors

Author

Sola, V., Arcidiacono, R., Boscardin, M., Cartiglia, N., Betta, G. -F. Dalla, Ficorella, F., Ferrero, M., Mandurrino, M., Pancheri, L., Paternoster, G., and Staiano, A.

Subjects

Physics - Instrumentation and Detectors

Abstract

Fondazione Bruno Kessler (FBK, Trento, Italy) has recently delivered its first 50 $\mu$m thick production of Ultra-Fast Silicon Detectors (UFSD), based on the Low-Gain Avalanche Diode design. These sensors use high resistivity Si-on-Si substrates, and have a variety of gain layer doping profiles and designs based on Boron, Gallium, Carbonated Boron and Carbonated Gallium to obtain a controlled multiplication mechanism. Such variety of gain layers will allow identifying the most radiation hard technology to be employed in the production of UFSD, to extend their radiation resistance beyond the current limit of $\phi \sim$ 10$^{15}$ n$_{eq}$/cm$^2$. In this paper, we present the characterisation, the timing performances, and the results on radiation damage tolerance of this new FBK production., Comment: 16 pages, 13 figures, 11th International "Hiroshima" Symposium on the Development and Application of Semiconductor Tracking Detectors (HSTD11) in conjunction with 2nd Workshop on SOI Pixel Detectors (SOIPIX2017) at OIST, Okinawa, Japan, Nuclear Instruments and Methods in Physics Research A (2018)

Published

2018

31. Radiation resistant LGAD design

Author

Ferrero, M., Arcidiacono, R., Barozzi, M., Boscardin, M., Cartiglia, N., Betta, G. F. Dalla, Galloway, Z., Mandurrino, M., Mazza, S., Paternoster, G., Ficorella, F., Pancheri, L., Sadrozinski, H-F W., Sola, V., Staiano, A., Seiden, A., Siviero, F., Tornago, M., and Zhao, Y.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

In this paper, we report on the radiation resistance of 50-micron thick LGAD detectors manufactured at the Fondazione Bruno Kessler employing several different doping combinations of the gain layer. LGAD detectors with gain layer doping of Boron, Boron low-diffusion, Gallium, Carbonated Boron and Carbonated Gallium have been designed and successfully produced. These sensors have been exposed to neutron fluences up to $\phi_n \sim 3 \cdot 10^{16}\; n/cm^2$ and to proton fluences up to $\phi_p \sim 9\cdot10^{15}\; p/cm^2$ to test their radiation resistance. The experimental results show that Gallium-doped LGADs are more heavily affected by initial acceptor removal than Boron-doped LGAD, while the presence of Carbon reduces initial acceptor removal both for Gallium and Boron doping. Boron low-diffusion shows a higher radiation resistance than that of standard Boron implant, indicating a dependence of the initial acceptor removal mechanism upon the implant width. This study also demonstrates that proton irradiation is at least twice more effective in producing initial acceptor removal, making proton irradiation far more damaging than neutron irradiation., Comment: 22 pages, 17 figures

Published

2018

32. A compensated design of the LGAD gain layer

Author

Sola, V., Arcidiacono, R., Asenov, P., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Croci, T., Ferrero, M., Fondacci, A., Gioachin, G., Giordanengo, S., Lantieri, L., Mandurrino, M., Menzio, L., Monaco, V., Morozzi, A., Moscatelli, F., Passeri, D., Pastrone, N., Paternoster, G., Siviero, F., Staiano, A., and Tornago, M.

Published

2022

33. Characterization of timing and spacial resolution of novel TI-LGAD structures before and after irradiation

Author

Senger, M., Bisht, A., Borghi, G., Boscardin, M., Centis Vignali, M., Ficorella, F., Ali, O. Hammad, Kilminster, B., Macchiolo, A., and Paternoster, G.

Published

2022

34. Development of LGAD sensors at FBK

Author

Bisht, A., Borghi, G., Boscardin, M., Centis Vignali, M., Ficorella, F., Hammad Ali, O., and Paternoster, G.

Published

2022

35. Beam test results of 25 and 35 μm thick FBK ultra-fast silicon detectors

Author

Carnesecchi, F., Strazzi, S., Alici, A., Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Centis Vignali, M., Cavazza, D., Dalla Betta, G. -F., Durando, S., Ferrero, M., Ficorella, F., Ali, O. Hammad, Mandurrino, M., Margotti, A., Menzio, L., Nania, R., Pancheri, L., Paternoster, G., Scioli, G., Siviero, F., Sola, V., Tornago, M., and Vignola, G.

Published

2023

36. Optimization of the gain layer design of ultra-fast silicon detectors

Author

Siviero, F., Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Vignali, M. Centis, Costa, M., Dalla Betta, G.-F., Ferrero, M., Ficorella, F., Gioachin, G., Mandurrino, M., Mazza, S., Menzio, L., Pancheri, L., Paternoster, G., Sadrozinski, H.-F.W., Seiden, A., Sola, V., and Tornago, M.

Published

2022

37. Plasma-based etching approach for GEM detector microfabrication at FBK for X-ray polarimetry in space

Author

Lega, A., primary, Novel, D., additional, Facchinelli, T., additional, Sgrò, C., additional, Baldini, L., additional, Minuti, M., additional, Boscardin, M., additional, Pepponi, G., additional, Iuppa, R., additional, Hall-Wilton, R., additional, and Latronico, L., additional

Published

2024

38. Characterization of thin carbonated LGADs after irradiation up to 2.5· 1015 n1 Mev eq./cm2

Author

Mulargia, R., primary, Arcidiacono, R., additional, Borghi, G., additional, Boscardin, M., additional, Cartiglia, N., additional, Centis Vignalis, M., additional, Costa, M., additional, Croci, T., additional, Ferrero, M., additional, Ficorella, F., additional, Fondacci, A., additional, Giordanengo, S., additional, Hammad Ali, O., additional, Hanna, C., additional, Lanteri, L., additional, Menzio, L., additional, Monaco, V., additional, Morozzi, A., additional, Moscatelli, F., additional, Passeri, D., additional, Pastrone, N., additional, Paternoster, G., additional, Siviero, F., additional, White, R.S., additional, and Sola, V., additional

Published

2024

39. Measurements and TCAD Simulations of Bulk and Surface Radiation Damage Effects in Silicon Detectors

Author

Moscatelli, F., Maccagnani, P., Passeri, D., Bilei, G. M., Servoli, L., Morozzi, A., Betta, G. -F. Dalla, Mendicino, R., Boscardin, M., and Zorzi, N.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

In this work we propose the application of a radiation damage model based on the introduction of deep level traps/recombination centers suitable for device level numerical simulation of radiation detectors at very high fluences (e.g. 1{\div}2 10^16 1-MeV equivalent neutrons per square centimeter) combined with a surface damage model developed by using experimental parameters extracted from measurements from gamma irradiated p-type dedicated test structures., Comment: 6 pages,12 figures. arXiv admin note: text overlap with arXiv:1611.10138

Published

2016

40. Resistive AC-Coupled Silicon Detectors: Principles of operation and first results from a combined analysis of beam test and laser data

Author

Tornago, M., Arcidiacono, R., Cartiglia, N., Costa, M., Ferrero, M., Mandurrino, M., Siviero, F., Sola, V., Staiano, A., Apresyan, A., Di Petrillo, K., Heller, R., Los, S., Borghi, G., Boscardin, M., Dalla Betta, G.-F., Ficorella, F., Pancheri, L., Paternoster, G., Sadrozinski, H., and Seiden, A.

Published

2021

41. Novel strategies for fine-segmented Low Gain Avalanche Diodes

Author

Paternoster, G., Borghi, G., Arcidiacono, R., Boscardin, M., Cartiglia, N., Centis Vignali, M., Dalla Betta, G.F., Ferrero, M., Ficorella, F., Mandurrino, M., Pancheri, L., Siviero, F., Sola, V., and Tornago, M.

Published

2021

42. 3D trenched-electrode pixel sensors: Design, technology and initial results

Author

Forcolin, G.T., Boscardin, M., Ficorella, F., Lai, A., Loi, A., Mendicino, R., Ronchin, S., and Dalla Betta, G.-F.

Published

2020

43. LGAD designs for Future Particle Trackers

Author

Cartiglia, N., Arcidiacono, R., Borghi, G., Boscardin, M., Costa, M., Galloway, Z., Fausti, F., Ferrero, M., Ficorella, F., Mandurrino, M., Mazza, S., Olave, E.J., Paternoster, G., Siviero, F., Sadrozinski, H. F-W., Sola, V., Staiano, A., Seiden, A., Tornago, M., and Zhao, Y.

Published

2020

44. Radiation resistant innovative 3D pixel sensors for the CMS upgrade at the High Luminosity LHC

Author

Meschini, M., Cassese, A., Ceccarelli, R., Viliani, L., Dinardo, M., Gennai, S., Zuolo, D., Messineo, A., Parolia, S., Ebrahimi, A., Pitzl, D., Steinbrück, G., Dalla Betta, G.F., Mendicino, R., Alimonti, G., Gemme, C., Boscardin, M., and Ronchin, S.

Published

2020

45. State-of-the-art and evolution of UFSD sensors design at FBK

Author

Arcidiacono, R., Borghi, G., Boscardin, M., Cartiglia, N., Costa, M., Dalla Betta, G.F., Fausti, F., Ferrero, M., Ficorella, F., Mandurrino, M., Mazza, S.M., Olave, E.J., Pancheri, L., Paternoster, G., Sadrozinski, H.-F.W., Sola, V., Staiano, A., Seiden, A., Siviero, F., Tornago, M., and Zhao, Y.

Published

2020

46. Analysis and numerical design of Resistive AC-Coupled Silicon Detectors (RSD) for 4D particle tracking

Author

Mandurrino, M., Arcidiacono, R., Boscardin, M., Cartiglia, N., Dalla Betta, G.-F., Ferrero, M., Ficorella, F., Pancheri, L., Paternoster, G., Siviero, F., Sola, V., Staiano, A., and Vignati, A.

Published

2020

47. New insights on boiling carbon dioxide flow in mini- and micro-channels for optimal silicon detector cooling

Author

Hellenschmidt, D., Bomben, M., Calderini, G., Boscardin, M., Crivellari, M., Ronchin, S., and Petagna, P.

Published

2020

48. Performance of new radiation-tolerant thin planar and 3D columnar n[formula omitted] on p silicon pixel sensors up to a maximum fluence of [formula omitted] n[formula omitted]/cm[formula omitted]

Author

Boscardin, M., Ceccarelli, R., Dalla Betta, G.F., Darbo, G., Dinardo, M.E., Giacomini, G., Menasce, D., Mendicino, R., Meschini, M., Messineo, A., Moroni, L., Rivera, R., Ronchin, S., Sultan, D.M.S., Uplegger, L., Viliani, L., Zoi, I., and Zuolo, D.

Published

2020

49. A prototype 4D-tracking demonstrator based on the TimeSPOT developments

Author

Loi, A., primary, Addison, M., additional, Anderlini, L., additional, Brundu, D., additional, Boscardin, M., additional, Cadeddu, S., additional, Cardini, A., additional, Cossu, G.M., additional, Dalla Betta, G.-F., additional, Frontini, L., additional, Garau, M., additional, Lai, A., additional, La Delfa, L., additional, Lampis, A., additional, Liberali, V., additional, Passaleva, G., additional, Piccolo, L., additional, Ronchin, S., additional, Stabile, A., additional, and Veltri, M., additional

Published

2024

50. Testbeam and Laboratory Characterization of CMS 3D Pixel Sensors

Author

Bubna, M., Alagoz, E., Krzywda, A., Koybasi, O., Arndt, K., Bortoletto, D., Shipsey, I., Bolla, G., Kok, A., Hansen, T. -E., Hansen, T. A., Jensen, G. U., Brom, J. M., Boscardin, M., Chramowicz, J., Cumalat, J., Betta, G. F. Dalla, Dinardo, M., Godshalk, A., Jones, M., Krohn, M. D., Kumar, A., Lei, C. M., Moroni, L., Perera, L., Povoli, M., Prosser, A., Rivera, R., Solano, A., Obertino, M. M., Kwan, S., Uplegger, L., Via, C. D., Vigani, L., and Wagner, S.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The pixel detector is the innermost tracking device in CMS, reconstructing interaction vertices and charged particle trajectories. The sensors located in the innermost layers of the pixel detector must be upgraded for the ten-fold increase in luminosity expected with the High- Luminosity LHC (HL-LHC) phase. As a possible replacement for planar sensors, 3D silicon technology is under consideration due to its good performance after high radiation fluence. In this paper, we report on pre- and post- irradiation measurements for CMS 3D pixel sensors with different electrode configurations. The effects of irradiation on electrical properties, charge collection efficiency, and position resolution of 3D sensors are discussed. Measurements of various test structures for monitoring the fabrication process and studying the bulk and surface properties, such as MOS capacitors, planar and gate-controlled diodes are also presented., Comment: 14 pages

Published

2014