Your search keyword '"Bonechi, S."' showing total 8 results

1. CaloCube: A novel calorimeter for high-energy cosmic rays in space

Author

Cattaneo, P.W., Adriani, O., Albergo, S., Auditore, L., Basti, A., Berti, E., Bigongiari, G., Bonechi, L., Bonechi, S., Bongi, M., Bonvicini, V., Bottai, S., Brogi, P., Carotenuto, G., Castellini, G., D'Alessandro, R., Detti, S., Fasoli, M., Finetti, N., Italiano, A., Lenzi, P., Maestro, P., Marrocchesi, P.S., Miritello, M., Mori, N., Olmi, M., Orzan, G., Pacini, L., Papini, P., Pellegriti, M.G., Rappoldi, A., Ricciarini, S., Rossella, M., Spillantini, P., Starodubtsev, O., Stolzi, F., Suh, J.E., Sulaj, A., Tiberio, A., Tricomi, A., Trifirò, A., Trimarchi, M., Vannuccini, E., Vedda, A., Zampa, G., Zampa, N., Zerbo, B., Cattaneo, P, Adriani, O, Albergo, S, Auditore, L, Basti, A, Berti, E, Bigongiari, G, Bonechi, L, Bonechi, S, Bongi, M, Bonvicini, V, Bottai, S, Brogi, P, Carotenuto, G, Castellini, G, D'Alessandro, R, Detti, S, Fasoli, M, Finetti, N, Italiano, A, Lenzi, P, Maestro, P, Marrocchesi, P, Mori, N, Olmi, M, Orzan, G, Pacini, L, Papini, P, Pellegriti, M, Rappoldi, A, Ricciarini, S, Rossella, M, Sciutto, A, Spillantini, P, Starodubtsev, O, Stolzi, F, Suh, J, Sulaj, A, Tiberio, A, Tricomi, A, Trifirò, A, Trimarchi, M, Vannuccini, E, Vedda, A, Zampa, G, and Zampa, N

Subjects

Scintillators and scintillating fibres and light guide, Physics - Instrumentation and Detectors, Physics::Instrumentation and Detectors, FOS: Physical sciences, Cosmic ray, 01 natural sciences, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Calorimeters, 0302 clinical medicine, Optics, 0103 physical sciences, Ultra-high-energy cosmic ray, Scintillators and scintillating fibres and light guides, Detectors and Experimental Techniques, Calorimeter methods, Absorption (electromagnetic radiation), physics.ins-det, Instrumentation, Mathematical Physics, Physics, Calorimeter, Large Hadron Collider, Calorimeter methods, Calorimeters, Scintillators and scintillating fibres and light guides, Space instrumentation, Instrumentation, Mathematical Physics, 010308 nuclear & particles physics, business.industry, Resolution (electron density), Instrumentation and Detectors (physics.ins-det), Space instrumentation, FIS/01 - FISICA SPERIMENTALE, Calorimeter method, Particle, Granularity, business, Infrastructure for advanced calorimeters [14]

Abstract

In order to extend the direct observation of high-energy cosmic rays up to the PeV region, highly performing calorimeters with large geometrical acceptance and high energy resolution are required. Within the constraint of the total mass of the apparatus, crucial for a space mission, the calorimeters must be optimized with respect to their geometrical acceptance, granularity and absorption depth. CaloCube is a homogeneous calorimeter with cubic geometry, to maximise the acceptance being sensitive to particles from every direction in space; granularity is obtained by relying on small cubic scintillating crystals as active elements. Different scintillating materials have been studied. The crystal sizes and spacing among them have been optimized with respect to the energy resolution. A prototype, based on CsI(Tl) cubic crystals, has been constructed and tested with particle beams. Some results of tests with different beams at CERN are presented., Comment: Seven pages, seven pictures. Proceedings of INSTR17 Novosibirsk

Published

2017

2. CaloCube: a novel calorimeter for high-energy cosmic rays in space.

Author

Rappoldi, A., Cattaneo, P. W., Adriani, O., Agnesi, A., Albergo, S., Auditore, L., Basti, A., Berti, E., Bigongiari, G., Bonechi, L., Bonechi, S., Bongi, M., Bonvicini, V., Bottai, S., Brogi, P., Cappello, G., Carotenuto, G., Castellini, G., D'Alessandro, R., and Detti, S.

Subjects

COSMIC rays, CALORIMETERS, PARTICLE beams, CRYSTAL structure, PHOTODIODES, PARTICLE physics

Abstract

CaloCube is an R&D project borne to develop a novel calorimeter design, optimized for high-energy cosmic ray measurements in space. A small prototype made of CsI(T1) elements has been built and tested on particle beams. A final version, made of 5×5×18 crystals and with dual readout (two photodiodes for each crystal), to cover the full required dynamic range, is under construction and will be tested at CERN SPS in Summer 2016. The dual readout compensation technique were developed and the feasibility to e×tract Č erenkov signals from CsI crystals verified. [ABSTRACT FROM AUTHOR]

Published

2017

3. The CALorimetric Electron Telescope (CALET) for high-energy astroparticle physics on the International Space Station.

Author

Adriani, O., Akaike, Y., Asano, K., Asaoka, Y., Bagliesi, M. G., Bigongiari, G., Binns, W. R., Bonechi, S., Bongi, M., Buckley, J. H., Castellini, G., Cherry, M. L., Collazuol, G., Ebisawa, K., Di Felice, V., Fuke, H., Guzik, T. G., Hams, T., Hareyama, M., and Hasebe, N.

Subjects

NUCLEAR astrophysics research, COSMIC rays, ELECTRON research, GAMMA ray bursts, DARK matter, CALORIMETERS

Abstract

The CALorimetric Electron Telescope (CALET) is a space experiment, currently under development by Japan in collaboration with Italy and the United States, which will measure the flux of cosmic-ray electrons (and positrons) up to 20 TeV energy, of gamma rays up to 10 TeV, of nuclei with Z from 1 to 40 up to 1 PeV energy, and will detect gamma-ray bursts in the 7 keV to 20 MeV energy range during a 5 year mission. These measurements are essential to investigate possible nearby astrophysical sources of high energy electrons, study the details of galactic particle propagation and search for dark matter signatures. The main detector of CALET, the Calorimeter, consists of a module to identify the particle charge, followed by a thin imaging calorimeter (3 radiation lengths) with tungsten plates interleaving scintillating fibre planes, and a thick energy measuring calorimeter (27 radiation lengths) composed of lead tungstate logs. The Calorimeter has the depth, imaging capabilities and energy resolution necessary for excellent separation between hadrons, electrons and gamma rays. The instrument is currently being prepared for launch (expected in 2015) to the International Space Station ISS, for installation on the Japanese Experiment Module - Exposure Facility (JEM-EF). [ABSTRACT FROM AUTHOR]

Published

2015

4. On-orbit operations and offline data processing of CALET onboard the ISS.

Author

Asaoka, Y., Ozawa, S., Torii, S., Adriani, O., Akaike, Y., Asano, K., Bagliesi, M.G., Bigongiari, G., Binns, W.R., Bonechi, S., Bongi, M., Brogi, P., Buckley, J.H., Cannady, N., Castellini, G., Checchia, C., Cherry, M.L., Collazuol, G., Di Felice, V., and Ebisawa, K.

Subjects

*CALORIMETERS, *CALORIMETER calibration, *COSMIC rays, *GAMMA rays

Abstract

The CALorimetric Electron Telescope (CALET), launched for installation on the International Space Station (ISS) in August, 2015, has been accumulating scientific data since October, 2015. CALET is intended to perform long-duration observations of high-energy cosmic rays onboard the ISS. CALET directly measures the cosmic-ray electron spectrum in the energy range of 1 GeV to 20 TeV with a 2% energy resolution above 30 GeV. In addition, the instrument can measure the spectrum of gamma rays well into the TeV range, and the spectra of protons and nuclei up to a PeV. In order to operate the CALET onboard ISS, JAXA Ground Support Equipment (JAXA-GSE) and the Waseda CALET Operations Center (WCOC) have been established at JAXA and Waseda University, respectively. Scientific operations using CALET are planned at WCOC, taking into account orbital variations of geomagnetic rigidity cutoff. Scheduled command sequences are used to control the CALET observation modes on orbit. Calibration data acquisition by, for example, recording pedestal and penetrating particle events, a low-energy electron trigger mode operating at high geomagnetic latitude, a low-energy gamma-ray trigger mode operating at low geomagnetic latitude, and an ultra heavy trigger mode, are scheduled around the ISS orbit while maintaining maximum exposure to high-energy electrons and other high-energy shower events by always having the high-energy trigger mode active. The WCOC also prepares and distributes CALET flight data to collaborators in Italy and the United States. As of August 31, 2017, the total observation time is 689 days with a live time fraction of the total time of  ∼ 84%. Nearly 450 million events are collected with a high-energy ( E  > 10 GeV) trigger. In addition, calibration data acquisition and low-energy trigger modes, as well as an ultra-heavy trigger mode, are consistently scheduled around the ISS orbit. By combining all operation modes with the excellent-quality on-orbit data collected thus far, it is expected that a five-year observation period will provide a wealth of new and interesting results. [ABSTRACT FROM AUTHOR]

Published

2018

5. CaloCube: An isotropic spaceborne calorimeter for high-energy cosmic rays. Optimization of the detector performance for protons and nuclei.

Author

Adriani, O., Albergo, S., Auditore, L., Basti, A., Berti, E., Bigongiari, G., Bonechi, L., Bonechi, S., Bongi, M., Bonvicini, V., Bottai, S., Brogi, P., Carotenuto, G., Castellini, G., Cattaneo, P.W., Daddi, N., D’Alessandro, R., Detti, S., Finetti, N., and Italiano, A.

Subjects

*CALORIMETERS, *COSMIC rays, *PROTONS, *GALACTIC nuclei, *ISOTROPIC properties, *SCINTILLATORS

Abstract

The direct detection of high-energy cosmic rays up to the PeV region is one of the major challenges for the next generation of space-borne cosmic-ray detectors. The physics performance will be primarily determined by their geometrical acceptance and energy resolution. CaloCube is a homogeneous calorimeter whose geometry allows an almost isotropic response, so as to detect particles arriving from every direction in space, thus maximizing the acceptance. A comparative study of different scintillating materials and mechanical structures has been performed by means of Monte Carlo simulation. The scintillation-Cherenkov dual read-out technique has been also considered and its benefit evaluated. [ABSTRACT FROM AUTHOR]

Published

2017

6. Energy calibration of CALET onboard the International Space Station.

Author

Asaoka, Y., Akaike, Y., Komiya, Y., Miyata, R., Torii, S., Adriani, O., Asano, K., Bagliesi, M.G., Bigongiari, G., Binns, W.R., Bonechi, S., Bongi, M., Brogi, P., Buckley, J.H., Cannady, N., Castellini, G., Checchia, C., Cherry, M.L., Collazuol, G., and Di Felice, V.

Subjects

*TELESCOPES, *ELECTRON spectroscopy, *COSMIC rays, *CALORIMETERS

Abstract

In August 2015, the CALorimetric Electron Telescope (CALET), designed for long exposure observations of high energy cosmic rays, docked with the International Space Station (ISS) and shortly thereafter began to collect data. CALET will measure the cosmic ray electron spectrum over the energy range of 1 GeV to 20 TeV with a very high resolution of 2% above 100 GeV, based on a dedicated instrument incorporating an exceptionally thick 30 radiation-length calorimeter with both total absorption and imaging (TASC and IMC) units. Each TASC readout channel must be carefully calibrated over the extremely wide dynamic range of CALET that spans six orders of magnitude in order to obtain a degree of calibration accuracy matching the resolution of energy measurements. These calibrations consist of calculating the conversion factors between ADC units and energy deposits, ensuring linearity over each gain range, and providing a seamless transition between neighboring gain ranges. This paper describes these calibration methods in detail, along with the resulting data and associated accuracies. The results presented in this paper show that a sufficient accuracy was achieved for the calibrations of each channel in order to obtain a suitable resolution over the entire dynamic range of the electron spectrum measurement. [ABSTRACT FROM AUTHOR]

Published

2017

7. CaloCube: A new-concept calorimeter for the detection of high-energy cosmic rays in space.

Author

Vannuccini, E., Adriani, O., Agnesi, A., Albergo, S., Auditore, L., Basti, A., Berti, E., Bigongiari, G., Bonechi, L., Bonechi, S., Bongi, M., Bonvicini, V., Bottai, S., Brogi, P., Carotenuto, G., Castellini, G., Cattaneo, P.W., D'Alessandro, R., Detti, S., and Fasoli, M.

Subjects

*COSMIC rays, *NUCLEAR counters, *GEOMETRIC analysis, *CALORIMETERS, *NUCLEAR physics experiments

Abstract

The direct observation of high-energy cosmic rays, up to the PeV region, will increasingly rely on highly performing calorimeters, and the physics performance will be primarily determined by their geometrical acceptance and energy resolution. Thus, it is extremely important to optimize their geometrical design, granularity, and absorption depth, with respect to the total mass of the apparatus, which is among the most important constraints for a space mission. Calocube is a homogeneous calorimeter whose basic geometry is cubic and isotropic, so as to detect particles arriving from every direction in space, thus maximizing the acceptance; granularity is obtained by filling the cubic volume with small cubic scintillating crystals. This design forms the basis of a three-year R & D activity which has been approved and financed by INFN. A comparative study of different scintillating materials has been performed. Optimal values for the size of the crystals and spacing among them have been studied. Different geometries, besides the cubic one, and the possibility to implement dual-readout techniques have been investigated. A prototype, instrumented with CsI(Tl) cubic crystals, has been constructed and tested with particle beams. An overview of the obtained results will be presented and the perspectives for future space experiments will be discussed. [ABSTRACT FROM AUTHOR]

Published

2017

8. CaloCube: A new concept calorimeter for the detection of high energy cosmic rays in space

Author

E Berti, O Adriani, S Albergo, G Ambrosi, L Auditore, A Basti, G Bigongiari, L Bonechi, S Bonechi, M Bongi, V Bonvicini, S Bottai, P Brogi, G Cappello, P W Cattaneo, R D Alessandro, S Detti, M Duranti, M Fasoli, N Finetti, V Formato, M Ionica, A Italiano, P Lenzi, P Maestro, P S Marrocchesi, N Mori, G Orzan, M Olmi, L Pacini, P Papini, A Rappoldi, S Ricciarini, A Sciuto, G Silvestre, O Starodubtsev, F Stolzi, J E Suh, A Sulaj, A Tiberio, A Tricomi, A Trifirò, M Trimarchi, E Vannuccini, A Vedda, G Zampa, N Zampa, Berti, E, Adriani, O, Albergo, S, Ambrosi, G, Auditore, L, Basti, A, Bigongiari, G, Bonechi, L, Bonechi, S, Bongi, M, Bonvicini, V, Bottai, S, Brogi, P, Cappello, G, Cattaneo, P, Alessandro, R, Detti, S, Duranti, M, Fasoli, M, Finetti, N, Formato, V, Ionica, M, Italiano, A, Lenzi, P, Maestro, P, Marrocchesi, P, Mori, N, Orzan, G, Olmi, M, Pacini, L, Papini, P, Rappoldi, A, Ricciarini, S, Sciuto, A, Silvestre, G, Starodubtsev, O, Stolzi, F, Suh, J, Sulaj, A, Tiberio, A, Tricomi, A, Trifir, A, Trimarchi, M, Vannuccini, E, Vedda, A, Zampa, G, and Zampa, N

Subjects

Energy resolutions, History, Calorimeters, CsI, Physics::Instrumentation and Detectors, calorimeter, energy resolution, High Energy Physics::Experiment, High energy physics, Cosmic rays, Computer Science Applications, Education, crystal

Abstract

Given the good performances in terms of geometrical acceptance and energy resolution, calorimeters are the best suited detectors to measure high energy cosmic rays directly in space. However, in order to exploit this potential, the design of calorimeters must be carefully optimized to take into account all limitations related to space missions, due mainly to the mass of the experimental apparatus. CaloCube is a three years R&D project, approved and financed by INFN in 2014, aiming to optimize the design of a space-borne calorimeter by the use of a cubic, homogeneous and isotropic geometry. In order to maximize detector performances with respect to the total mass of the apparatus, comparative studies on different scintillating materials, different sizes of crystals and different spacings among them have been performed making use of Monte Carlo simulations. In parallel to this activity, several prototypes instrumented with CsI:Tl cubic crystals have been constructed and tested with particle beams (muons, electrons, protons and ions). Both simulations and prototypes showed that the CaloCube design leads to a good particle energy resolution (< 2% for electromagnetic showers, < 40% for hadronic showers) and a good effective geometric factor (> 3:5 m2 sr for electromagnetic showers, > 2:5 m2 sr for hadronic showers). Thanks to these performances, in 5 years of operation it would be possible to measure the ux of electrons+positrons up to some tens of TeV and the uxes of protons and nuclei up to some units of PeV/nucleon, hence extending these measurements by at least one order of magnitude in energy compared to the experiments currently operating in space.

Published

2019