论文信息 - The CALOCUBE project for a space based cosmic ray experiment: design, construction, and first performance of a high granularity calorimeter prototype - 字舞流文

The CALOCUBE project for a space based cosmic ray experiment: design, construction, and first performance of a high granularity calorimeter prototype

Current research in High Energy Cosmic Ray Physics touches on fundamental questions regarding the origin of cosmic rays, their composition, the acceleration mechanisms, and their production. Unambiguous measurements of the energy spectra and of the composition of cosmic rays at the “knee” region could provide some of the answers to the above questions. So far only ground based observations, which rely on sophisticated models describing high energy interactions in the Earth's atmosphere, have been possible due to the extremely low particle rates at these energies. A calorimetry based space experiment that could provide not only flux measurements but also energy spectra and particle identification, would certainly overcome some of the uncertainties of ground based experiments. Given the expected particle fluxes, a very large acceptance is needed to collect a sufficient quantity of data, in a time compatible with the duration of a space mission. This in turn, contrasts with the lightness and compactness requirements for space based experiments. We present a novel idea in calorimetry which addresses these issues whilst limiting the mass and volume of the detector. In this paper we report on a four year R&D program where we investigated materials, coatings, photo-sensors, Front End electronics, and mechanical structures with the aim of designing a high performance, high granularity calorimeter with the largest possible acceptance. Details are given of the design choices, component characterisation, and of the construction of a sizeable prototype (Calocube) which has been used in various tests with particle beams.

A. Basti | N. Zampa | P. Spillantini | R. Cecchi | G. Carotenuto | S. Albergo | G. Cappello | A. Tricomi | P. Lenzi | P. Maestro | A. Vedda | P. Cattaneo | F. Morsani | N. Finetti | P. Papini | O. Adriani | S. Bottai | M. Bongi | V. Bonvicini | N. Mori | S. Ricciarini | E. Vannuccini | G. Zampa | S. J.E. | P. Marrocchesi | A. Trifirò | A. Rappoldi | A. Sciuto | L. Auditore | E. Berti | G. Bigongiari | L. Bonechi | P. Brogi | G. Castellini | S. Detti | A. Italiano | G. Orzan | M. Olmi | L. Pacini | M. Pellegriti | O. Starodubtsev | F. Stolzi | J. Suh | A. Sulaj | A. Tiberio | M. Trimarchi | M. Fasoli | C. Checchia | A. Orsini | L. Stiaccini | R. D’Alessandro | C. P.W. | M. Manetti | M. P.S. | P. M.G. | N. N.Zampa

[1] A. Basti,et al. CaloCube: a new concept calorimeter for the detection of high energy cosmic rays in space , 2017, Journal of Physics: Conference Series.

[2] A. Basti,et al. CaloCube: an isotropic spaceborne calorimeter for high-energy cosmic rays. Optimization of the detector performance for protons and nuclei☆ , 2017 .

[3] S. Albergo,et al. CLASSiC: Cherenkov light detection with silicon carbide , 2017 .

[4] W. Hanlon. Progress towards understanding the analyses of mass composition made by the Auger and Telescope Array Collaborations , 2016 .

[5] Haibing Hu,et al. Knee of the cosmic hydrogen and helium spectrum below 1 PeV measured by ARGO-YBJ and a Cherenkov telescope of LHAASO , 2015, 1502.03164.

[6] Danzengluobu,et al. Energy spectrum of cosmic protons and helium nuclei by a hybrid measurement at 4300 m a.s.l. , 2014, 1401.6987.

[7] Kuppusamy Thayalan,et al. Radiation Detection and Measurements , 2014 .

[8] D. Groom. Degradation of resolution in a homogeneous dual-readout hadronic calorimeter , 2012, 1210.2334.

[9] Illiam,et al. Progress towards understanding the analyses of mass composition made by the Auger and Telescope Array Collaborations , 2013 .

[10] P. Marrocchesi. CALET: A calorimeter-based orbital observatory for High Energy Astroparticle Physics , 2012 .

[11] Pierre Auger,et al. Measurements of the Longitudinal Development of Air Showers with the Pierre Auger Observatory , 2012 .

[12] Danzengluobu,et al. Cosmic-ray energy spectrum around the knee obtained by the Tibet experiment and future prospects , 2011 .

[13] L. Bosisio,et al. Noise Characterization of Double-Sided Silicon Microstrip Detectors With Punch-Through Biasing , 2008, IEEE Transactions on Nuclear Science.

[14] N. Zampa,et al. A Double-Gain, Large Dynamic Range Front-end ASIC With A/D Conversion for Silicon Detectors Read-Out , 2010, IEEE Transactions on Nuclear Science.

[15] J. R. Thomas,et al. Indications of proton-dominated cosmic-ray composition above 1.6 EeV. , 2009, Physical review letters.

[16] Yonggang Wang,et al. Physical Properties of LYSO Scintillator for NN-PET Detectors , 2009, 2009 2nd International Conference on Biomedical Engineering and Informatics.

[17] et al,et al. Probing the ATIC peak in the cosmic-ray electron spectrum with H.E.S.S. , 2009, 0905.0105.

[18] R. Wigmans. Recent results from the DREAM project , 2009 .

[19] G. Ciapetti,et al. Dual-Readout calorimetry with crystal calorimeters , 2009 .

[20] A. R. Bazer-Bachi,et al. Energy spectrum of cosmic-ray electrons at TeV energies. , 2008, Physical review letters.

[21] G. Ciapetti,et al. Separation of crystal signals into scintillation and Cherenkov components , 2008 .

[22] Ren-Yuan Zhu,et al. Emission Spectra of LSO and LYSO Crystals Excited by UV Light, X-Ray and $\gamma$-ray , 2008, IEEE Transactions on Nuclear Science.

[23] Rihua Mao,et al. Emission spectra of LSO and LYSO crystals excited by UV light, x-ray and γ-ray , 2007, 2007 IEEE Nuclear Science Symposium Conference Record.

[24] N. Zampa,et al. CASIS1.1: a very high dynamic range front- end electronics with integrated Cyclic ADC for calorimetry applications , 2006, 2007 IEEE Nuclear Science Symposium Conference Record.

[25] M. Thiel,et al. High-Energy Photon Detection With LYSO Crystals , 2006, 2006 IEEE Nuclear Science Symposium Conference Record.

[26] E. al.,et al. KASCADE measurements of energy spectra for elemental groups of cosmic rays: Results and open problems , 2005, astro-ph/0505413.

[27] O. Zelenskaya,et al. Comparative light yield measurements of oxide and alkali halide scintillators , 2005 .

[28] H. Shimizu,et al. Chemical composition of ultra-high energy cosmic rays estimated by muon measurement with AGASA , 2005 .

[29] Frank Scholze,et al. Determination of the electron–hole pair creation energy for semiconductors from the spectral responsivity of photodiodes , 2000 .

[30] J F Ziegler,et al. Comments on ICRU report no. 49: stopping powers and ranges for protons and alpha particles. , 1999, Radiation research.

[31] Hayes,et al. Review of Particle Physics. , 1996, Physical review. D, Particles and fields.

[32] R. Roy,et al. Energy-light relation for CsI(T1) scintillators in heavy ion experiments at intermediate energies , 1994 .

[33] M. Ishii,et al. Effect of Surface Roughness and Crystal Shape on Performance of Bismuth Germanate Scintillators , 1986 .