The μ-RWELL for high rate application

Bencivenni, G.; Oliveira, Rui de; Felici, G.; Gatta, M.; Giovannetti, M.; Morello, G.; Lener, M. Poli

doi:10.1088/1748-0221/15/09/c09034

Cited by 7 publications

(2 citation statements)

References 15 publications

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“…• a laboratory for the development of gaseous detectors of novel concept -Detector Development Group, DDG. This infrastructure has its roots in the long standing tradition of LNF in the R&D, design and manufacturing of gaseous detectors, such as wire tubes operated in proportional or streamer mode (1985-1990), RPC with glass electrodes (1991-1994), large drift chamber (1995-1997) and Micro-Pattern-Gaseous-Detector (MPGDs -since 2000) for large high-energy-physics experiments [1];…”

Section: Infrastructures and Scientific Programmentioning

confidence: 99%

The reserach activity of the Frascati Laboratory

Gianotti¹

2020

J. Inst.

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The Frascati National Laboratory (LNF) is the largest and the oldest among the National Laboratories of the Italian Institute for Nuclear Physics (INFN). Since its foundation in 1954, it has been devoted to two main activities: the development, construction and operation of particle accelerators; the design and construction of forefront detectors for particle, nuclear and astroparticle physics. The research program of LNF is focused on fundamental research, but interdisciplinary activity has grown of importance along the years, with a perfect balance between internal and external activities. The scientific program taking place at LNF, at present, is still centered on the DAΦNE complex, but in the last years, a second accelerator infrastructure, SPARC\_LAB, devoted to the study and development of new technique of particle acceleration is marking the path toward the future: EuPARXIA. This will be an European infrastructure for plasma acceleration development. In this paper, an overview of the research program of the Laboratory and of the future perspectives is presented.

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Section: Infrastructures and Scientific Programmentioning

confidence: 99%

The reserach activity of the Frascati Laboratory

Gianotti¹

2020

J. Inst.

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“…Their usage improves detector stability, making possible a higher gain in a single multiplication layer, a remarkable advantage for assembly, mass production and cost. Diamond-like carbon (DLC) resistive layers are the key ingredients for increasing the rate capability of MPGDs [97,98]. Nowadays, many intensive R&D activities and their diversified applications are pursued within the world-wide CERN-RD51 collaboration [99].…”

Section: Jinst 15 C10023mentioning

confidence: 99%

Next frontiers in particle physics detectors: INSTR2020 summary and a look into the future

Titov¹

2020

J. Inst.

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The physics goals of high luminosity particle accelerators, from LHC to HL-LHC and to the next generation of lepton colliders, have set quite stringent constraints on the future needs at the Instrumentation Frontier. Many technologies are reaching their sensitivity limit and new approaches need to be developed to overcome the currently irreducible technological challenges. The detrimental effect of the material budget and power consumption represents a very serious concern for a high-precision silicon vertex and tracking detectors. One of the most promising areas is CMOS sensors offering low mass and potentially radiation-hard technology for the future proton-proton and electron-positron colliders, intensity frontier and heavy-ion experiments. MPGDs have become a well-established technique in the fertile field of gaseous detectors; these will remain the primary choice whenever the large-area coverage with low material budget is required. Vacuum tube technology is inherently fast and new developments include advances in microchannel plates for photomultipliers with a potential for a picosecondtime resolution in large systems. Several novel concepts of picosecond-timing detectors will have numerous powerful applications in particle identification, pile-up rejection and event reconstruction, and serve numerous scientific goals. The story of modern calorimetry is a textbook example of physics research driving the development of an experimental method. Silicon photomultipliers have seen a rapid progress in the last decade, becoming the standard solution for scintillator-based devices. The integration of advanced electronics and data transmission functionalities plays an increasingly important role and needs to be addressed. Bringing the modern algorithmic advances from the field of machine learning from offline applications to online operations and trigger systems is another major challenge. The timescales spanned by future projects in particle physics, ranging from few years to many decades, constitute a challenge in itself, in addition to the complexity and diversity of the required accelerator and detector R&D. This paper summarizes advances and recent trends in the instrumentation techniques for particle physics experiments, largely based on the presentations given at the International Conference "Instrumentation for Colliding Beam Physics" (INSTR-20), held at BINP Novosibirsk, Russia, from 24 to

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Gaseous Detectors

Titov¹

2021

Handbook of Particle Detection and Imaging

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The μ-RWELL for high rate application

Cited by 7 publications

References 15 publications

The reserach activity of the Frascati Laboratory

The reserach activity of the Frascati Laboratory

Next frontiers in particle physics detectors: INSTR2020 summary and a look into the future

Gaseous Detectors

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