Radiation hardness of thin Low Gain Avalanche Detectors

Kramberger, G.; Carulla, M.; Cavallaro, E.; Cindro, V.; Flores, D.; Galloway, Z.; Grinstein, S.; Hidalgo, S.; Fadeyev, V.; Lange, J.; Mandić, I.; Medin, G.; Merlos, A.; McKinney-Martinez, F.; Mikuž, M.; Quirion, D.; Pellegrini, G.; Petek, M.; Sadrozinski, H.F.-W.; Seiden, A.; Zavrtanik, M.

doi:10.1016/j.nima.2018.02.018

Cited by 47 publications

(44 citation statements)

References 18 publications

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“…The fit of the convoluted Landau and Gaussian distributions to the data is also shown. The difference of factor ∼ 10 was observed in the most probable signal (parameter p1 of the fit) which is also expected from the measured gain [7] and the difference in the detector thickness. As the noise level is 20% larger for LGAD, due to higher capacitance (see Fig.…”

Section: Measurementssupporting

confidence: 73%

“…The first stage of amplification uses fast transimpedance amplifier designed by UCSC [15] followed by a second amplifier which gives signals large enough to be relatively easily recorded by a 40 GS/s digitizing oscilloscope with 2.5 GHz bandwidth. The reference time required for measurement of the time resolution was provided from a non-irradiated LGAD detector produced by HPK [7,15]. It is 50 µm thick, has a diameter of 0.8 mm and high gain of ∼ 60 at 330 V and room temperature.…”

Section: Measurementsmentioning

confidence: 99%

“…The time resolution of HPK-50D sensors was measured (in the same setup with a method described below) by using two such detectors and was determined to be 26 ps. More details on timing and charge collection measurements with these LGADs can be found in [7,15]. The electrons were collimated to an angle of < 1 • by a combination of collimator, small cell size and the circular opening in the PCB boards hosting the sensors.…”

Section: Measurementsmentioning

confidence: 99%

“…However, the gain degrades with irradiation [6,7]. The high gain of LGADs can be maintained at equivalent fluences below 10 15 cm −2 , where their performance has been demonstrated to fulfill the HL-LHC requirements [8].…”

Section: Introductionmentioning

confidence: 99%

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Timing performance of small cell 3D silicon detectors

Kramberger

Cindro

Flores

et al. 2019

Nuclear Instruments and Methods in Physics Research Section A:

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A silicon 3D detector with a single cell of 50 × 50 µm 2 was produced and evaluated for timing applications. The measurements of time resolution were performed for 90 Sr electrons with dedicated electronics used also for determining time resolution of Low Gain Avalanche Detectors (LGADs). The measurements were compared to those with LGADs and also simulations. The studies showed that the dominant contribution to the timing resolution comes from the time walk originating from different induced current shapes for hits over the cell area. This contribution decreases with higher bias voltages, lower temperatures and smaller cell sizes. It is around 30 ps for a 3D detector of 50 × 50 µm 2 cell at 150 V and -20 • C, which is comparable to the time walk due to Landau fluctuations in LGADs. It even improves for inclined tracks and larger pads composed of multiple cells. A good agreement between measurements and simulations was obtained, thus validating the simulation results. PACS: 85.30.De; 29.40.Wk; 29.40.Gx Work performed in the framework of the CERN-RD50 collaboration.

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Section: Measurementssupporting

confidence: 73%

Section: Measurementsmentioning

confidence: 99%

Section: Measurementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Timing performance of small cell 3D silicon detectors

Kramberger

Cindro

Flores

et al. 2019

Nuclear Instruments and Methods in Physics Research Section A:

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“…This is possible only in thin sensors (50-micron thick or less) where the external voltage can create an electric field of the order of 250-300 kV/cm without causing electrical breakdown in other areas of the detector. Figure 53 shows the bias voltage necessary to maintain a gain G = 10 as a function of irradiation for 50-micron thick CNM sensors implanted with a shallow gain layer, using the irradiation results from [45] (squares), the initial acceptor removal parameterisation of equation (5-4) with the value of the parameters shown in Figure 27, and the Massey model of impact ionization [27], The very good agreement between the WF2 predicted values and the measured points indicates the correctness of the initial acceptor removal model and the appropriate gain parameterisation of the Massey equations in this range of the electric field. The thick solid line indicates the bulk contribution to the total gain value (right y-axis): it starts to be important at ~1e15 n eq /cm 2 , and it becomes ~ 50% at ~2e15 n eq /cm 2 .…”

mentioning

confidence: 99%

4D tracking with ultra-fast silicon detectors

2017

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The evolution of particle detectors has always pushed the technological limit in order to provide enabling technologies to researchers in all fields of science. One archetypal example is the evolution of silicon detectors, from a system with a few channels 30 years ago, to the tens of millions of independent pixels currently used to track charged particles in all major particle physics experiments. Nowadays, silicon detectors are ubiquitous not only in research laboratories but in almost every high-tech apparatus, from portable phones to hospitals. In this contribution, we present a new direction in the evolution of silicon detectors for charge particle tracking, namely the inclusion of very accurate timing information. This enhancement of the present silicon detector paradigm is enabled by the inclusion of controlled low gain in the detector response, therefore increasing the detector output signal sufficiently to make timing measurement possible. After providing a short overview of the advantage of this new technology, we present the necessary conditions that need to be met for both sensor and readout electronics in order to achieve 4D tracking. In the last section, we present the experimental results, demonstrating the validity of our research path.

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Solid State Detectors for High Radiation Environments

Kramberger¹

2020

Particle Physics Reference Library

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Radiation hardness of thin Low Gain Avalanche Detectors

Cited by 47 publications

References 18 publications

Timing performance of small cell 3D silicon detectors

Timing performance of small cell 3D silicon detectors

4D tracking with ultra-fast silicon detectors

Solid State Detectors for High Radiation Environments

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