Particle production, transport, and identification in the regime of 
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Booth, Alexander; Charitonidis, N.; Chatzidaki, Panagiota; Karyotakis, Y.; Nowak, E.; Ortega-Ruiz, I.; Rosenthal, M.; Sala, P.

doi:10.1103/physrevaccelbeams.22.061003

Cited by 17 publications

(25 citation statements)

References 15 publications

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“…The H4-VLE beam line then accepts, momentum-selects and transports these particles to the ProtoDUNE-SP detector. The beam line is equipped with profile monitors, able to provide a measurement of each particle's momentum, trigger counters, able to determine a timeof-flight (TOF) with a total resolution of ∼900 ps on a distance of 28.575 m, and two threshold Cherenkov counters, one able to sustain a high-pressure radiator gas (HP), up to 15 bar and a second one able to sustain gases with lower pressures (LP), up to 5 bar [4]. The spectrometer resolution has been extrapolated from MonteCarlo simulation [5], a value of ∆p/p 2.5% has been determined assuming no material in the beam line for a central momentum of 12 GeV/c and position resolutions of 0.5 mm.…”

Section: H4-vle Beam Line Instrumentationmentioning

confidence: 99%

First calorimetric energy reconstruction of beam events with ARAPUCA light detector in protoDUNE-SP

Totani

Cavanna

2020

J. Inst.

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Section: H4-vle Beam Line Instrumentationmentioning

confidence: 99%

First calorimetric energy reconstruction of beam events with ARAPUCA light detector in protoDUNE-SP

Totani

Cavanna

2020

J. Inst.

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“…These techniques are discussed, for example, in Refs. [127,128]. After the momentum selection stage, it is usual to recombine the dispersed rays so that the particles exiting the momentum selection have, at first-order, trajectories independent of their momentum within the accepted momentum band.…”

Section: Momentum Selection and Final Focusing Stagesmentioning

confidence: 99%

Design and Diagnostics of High-Precision Accelerator Neutrino Beams

et al. 2021

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Neutrino oscillation physics has entered a new precision era, which poses major challenges to the level of control and diagnostics of the neutrino beams. In this paper, we review the design of high-precision beams, their current limitations, and the latest techniques envisaged to overcome such limits. We put emphasis on “monitored neutrino beams” and advanced diagnostics to determine the flux and flavor of the neutrinos produced at the source at the per-cent level. We also discuss ab-initio measurements of the neutrino energy–i.e., measurements performed without relying on the event reconstruction at the ν detector–to remove any flux induced bias in the determination of the cross sections.

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“…The construction of ProtoDUNE-SP started in September 2016 with the construction of the cryostat. In August 2018 the detector started to acquire data from a tagged particle beam, the H4 VLE [2]. After two months of beam data, the operation of ProtoDUNE-SP continued for about two years, recording cosmic ray events which allowed to extensively test the hardware and perform additional R&D.…”

Section: Protodune Single Phase At Cernmentioning

confidence: 99%

Construction, installation and operation of ProtoDUNE-SP

Bordoni¹

2021

Proceedings of 40th International Conference on High Energy Physics — PoS(ICHEP2020)

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The single-phase liquid argon TPC at CERN (ProtoDUNE-SP) is an engineering prototype for the first module of the DUNE far detector. This prototype, which has dimensions of a cube of about 10 m edge, provides full validation of the use of the membrane tank technology for large dimension cryostats. Furthermore, the very high performance of the protoDUNE-SP TPC with more than 500 days of continuous and stable operation, demonstrated the reliability of the LAr detection technology at a scale never tested before. In this talk we will review the main characteristics and milestones of the construction and installation of protoDUNE-SP which provide a series of benchmarks for DUNE. The performance for several different detector working points will also be discussed.

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Particle production, transport, and identification in the regime of 1−7 GeV/c

Cited by 17 publications

References 15 publications

First calorimetric energy reconstruction of beam events with ARAPUCA light detector in protoDUNE-SP

First calorimetric energy reconstruction of beam events with ARAPUCA light detector in protoDUNE-SP

Design and Diagnostics of High-Precision Accelerator Neutrino Beams

Construction, installation and operation of ProtoDUNE-SP

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