Publications of Francesco Arneodo: journal articles Figure 1: Citation report from ISI Web of Science (IF=31.0) [1] E. Aprile et al., First Axion Results from the XENON100 Experiment, arxiv.org (submitted to Phys. Rev. D) (2014) 1455, 1404.1455. [2] E. Aprile et al., Observation and applications of single-electron charge signals in the XENON100 experiment, Journal of Physics G: Nuclear and Particle Physics 41 (2014) 035201. [3] E. Aprile et al., Analysis of the XENON100 dark matter search data, Astroparticle Physics 54 (2014) 11. [4] E. Aprile et al., The neutron background of the XENON100 dark matter search experiment, Journal of Physics G: Nuclear and Particle Physics 40 (2013) 115201. [5] F. Arneodo, The XENON100 experiment and the evolution to the ton scale, Nuclear Instruments and Methods in Physics Research A 718 (2013) 450. [6] F. Arneodo, Physics (almost) without accelerators, Il Nuovo Cimento C (2013) 1. [7] E. Aprile et al., Response of the XENON100 dark matter detector to nuclear recoils, Physical Review D 88 (2013) 012006. [8] E. Aprile et al., Limits on Spin-Dependent WIMP-Nucleon Cross Sections from 225 Live Days of XENON100 Data, Physical Review Letters 111 (2013) 021301. [9] F. Arneodo, Dark Matter Searches, arxiv.org (2013), 1301.0441v1. [10] E. Aprile et al., The distributed Slow Control System of the XENON100 experiment, Journal of Instrumentation 7 (2012) T12001. 1
[11] E. Aprile et al., Dark Matter Results from 225 Live Days of XENON100 Data., Physical Review Letters 109 (2012) 181301. [12] E. Aprile et al., The XENON100 dark matter experiment, Astroparticle Physics (2012). [13] V. Hannen et al., Limits on the release of Rb isotopes from a zeolite based 83mKr calibration source for the XENON project, Journal of Instrumentation 6 (2011) P10013. [14] E. Aprile et al., Astroparticle Physics, Astroparticle Physics 35 (2011) 43. [15] E. Aprile et al., Likelihood approach to the first dark matter results from XENON100, Physical Review D 84 (2011) 052003. [16] E. Aprile et al., Implications on inelastic dark matter from 100 live days of XENON100 data, Physical Review D 84 (2011) 061101. [17] E. Aprile et al., Dark Matter Results from 100 Live Days of XENON100 Data, Physical Review Letters 107 (2011) 131302. [18] E. Aprile et al., Design and performance of the XENON10 dark matter experiment, Astroparticle Physics 34 (2011) 679. [19] E. Aprile et al., Study of the electromagnetic background in the XENON100 experiment, Physical Review D 83 (2011) 082001. [20] J. Angle et al., Search for Light Dark Matter in XENON10 Data, Physical Review Letters 107 (2011) 051301. [21] E. Aprile et al., First Dark Matter Results from the XENON100 Experiment, Physical Review Letters 105 (2010) 131302. [22] I. Collaboration, Energy reconstruction of electromagnetic showers from pi 0 decays with the ICARUS T600 Liquid Argon TPC, Acta Physica Polonica B 41 (2010) 103. [23] J. Abraham et al., The fluorescence detector of the Pierre Auger Observatory, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 620 (2010) 227. [24] J. Angle et al., Constraints on inelastic dark matter from XENON10, Physical Review D 80 (2009) 115005. [25] R. Antolini et al., Radiation Measurements, Radiation Measurements 44 (2009) 926. [26] P.A. Collaboration et al., Atmospheric effects on extensive air showers observed with the surface detector of the Pierre Auger observatory, Astroparticle Physics 32 (2009) 89. [27] M. Aglietta et al., Measurement of the proton-air inelastic cross section at s2tev from the EAS-TOP experiment, Physical Review D 79 (2009) 032004. [28] P. Sorensen et al., The scintillation and ionization yield of liquid xenon for nuclear recoils, Nuclear Inst. and Methods in Physics Research, A 601 (2009) 339. 2
[29] F. Arneodo and W. Fulgione, A low background facility inside the LVD detector at Gran Sasso, Journal of Cosmology and Astroparticle Physics 2 (2009) 028. [30] M. Aglietta et al., Evolution of the Cosmic-Ray Anisotropy Above 1014 ev, The Astrophysical Journal Letters 692 (2009) L130. [31] J. Abraham et al., Upper limit on the cosmic-ray photon fraction at EeV energies from the Pierre Auger Observatory, Astroparticle Physics (2009). [32] J. Abraham et al., Limit on the diffuse flux of ultrahigh energy tau neutrinos with the surface detector of the Pierre Auger Observatory, Physical Review D 79 (2009) 102001. [33] P.A. Collaboration et al., The surface detector system of the Pierre Auger Observatory, Nuclear Instruments and Methods in Physics Research Section A 586 (2008) 409. [34] M. Aglietta et al., Temperature variations in the low stratosphere (50 200 hpa) monitored by means of the atmospheric muon flux, Il Nuovo Cimento C 31 (2008) 175. [35] J. Angle et al., Limits on Spin-Dependent WIMP-Nucleon Cross Sections from the XENON10 Experiment, Physical Review Letters 101 (2008) 91301. [36] J. Angle et al., First results from the XENON10 dark matter experiment at the Gran Sasso National Laboratory, Physical Review Letters 100 (2008) 21303. [37] J. Abraham et al., Upper limit on the diffuse flux of ultrahigh energy tau neutrinos from the Pierre Auger Observatory, Physical Review Letters 100 (2008) 211101. [38] J. Abraham et al., Upper limit on the cosmic-ray photon flux above 1019eV using the surface detector of the Pierre Auger Observatory, Astroparticle Physics 29 (2008) 243. [39] J. Abraham et al., Correlation of the highest-energy cosmic rays with the positions of nearby active galactic nuclei, Astroparticle Physics 29 (2008) 188. [40] J. Abraham et al., Observation of the suppression of the flux of cosmic rays above 4x1019 ev, Physical Review Letters 101 (2008) 061101. [41] J. Abraham et al., Correlation of the highest energy cosmic rays with nearby extragalactic objects, SCIENCE (2007). [42] J. Abraham et al., Anisotropy studies around the galactic centre at EeV energies with the Auger Observatory, Astroparticle Physics 27 (2007) 244. [43] J. Abraham et al., An upper limit to the photon fraction in cosmic rays above 1019 ev from the Pierre Auger Observatory, Astroparticle Physics 27 (2007) 155. [44] F. Arneodo et al., Performance of a liquid argon time projection chamber exposed to the CERN West Area Neutrino Facility neutrino beam, Physical Review D 74 (2006) 112001. [45] X. Bertou et al., Calibration of the surface array of the Pierre Auger Observatory, Nuclear Instruments and Methods in Physics Research Section A 568 (2006) 839. [46] A. Ankowski et al., Measurement of through-going particle momentum by means of multiple scattering with the ICARUS T600 TPC, The European Physical Journal C 48 (2006) 667. 3
[47] A. Ankowski et al., Characterization of ETL 9357FLA photomultiplier tubes for cryogenic temperature applications, Nuclear Instruments & Methods In Physics Research Section A- Accelerators Spectrometers Detectors And Associated Equipment 556 (2006) 146. [48] F. Arneodo, MINOS, OPERA, ICARUS, Nuclear Physics B Proceedings Supplements 138 (2005) 363. [49] F. Arneodo, Status and Performances of the AUGER Surface Detector Array, (2005). [50] D. Allard et al., The trigger system of the Pierre Auger Surface Detector: operation, efficiency and stability, Arxiv preprint astro-ph/0510320 (2005). [51]. Aglietta et al., The cosmic ray primary composition in the knee region through the EAS electromagnetic and muon measurements at EAS-TOP, Astroparticle Physics 21 (2004) 14. [52] M. Aglietta et al., The cosmic ray proton, helium and CNO fluxes in the 100 TeV energy region from TeV muons and EAS atmospheric Cherenkov light observations of MACRO and EAS-TOP, Astroparticle Physics 21 (2004) 223. [53] S. Amoruso et al., Study of electron recombination in liquid argon with the ICARUS TPC, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 523 (2004) 275. [54] T.I. Collaboration, Measurement of the decay spectrum with the ICARUS liquid Argon TPC, The European Physical Journal C 33 (2004) 233. [55]. Aglietta et al., The cosmic ray primary composition between 10 15 and 10 16 ev from Extensive Air Showers electromagnetic and TeV muon data, Astroparticle Physics 20 (2004) 12. [56] M. Antonello, F. Arneodo and A. BADERTSCHER, Detection of Cherenkov light emission in liquid argon, Nuclear instruments &... (2004). [57] S. Amerio et al., Design, construction and tests of the ICARUS T600 detector, Nuclear Inst. and Methods in Physics Research, A 527 (2004) 329. [58] S. Amoruso et al., Analysis of the liquid Argon purity in the ICARUS T600 TPC, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 516 (2004) 68. [59]. Arneodo et al., Observation of long ionizing tracks with the ICARUS T600 first half-module, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 508 (2003) 8. [60] M. Aglietta et al., Measurement of the cosmic ray hadron spectrum up to 30 TeV at mountain altitude: the primary proton spectrum, Astroparticle Physics 19 (2003) 329. [61] F. Arneodo et al., Performance of the 10 m 3 ICARUS liquid Argon prototype, Nuclear Inst. and Methods in Physics Research, A 498 (2003) 292. [62] F. Arneodo, Atmospheric and Solar Neutrino Detection with the ICARUS T600 Module, (2002). 4
[63] F. Arneodo et al., The ICARUS liquid argon time projection chamber, Nuclear Instruments and Methods in Physics Research Section A 471 (2001) 272. [64] F. Arneodo and I. Collaboration, Operation of a 10 m 3 ICARUS detector module, Nuclear Instruments and Methods in Physics Research Section A 461 (2001) 286. [65] F. Arneodo et al., Electron beam generation from semiconductor photocathodes, Review of Scientific Instruments 72 (2001) 63. [66] M. Aglietta et al., Search for Eγ 10 13 ev γ-ray transients through the BAKSAN and EAS-TOP correlated data, Astroparticle Physics 14 (2000) 189. [67] F. Arneodo et al., First observation of 140-cm drift ionizing tracks in the ICARUS liquidargon TPC, Nuclear Instruments and Methods in Physics Research Section A 449 (2000) 36. [68] F. Arneodo et al., Scintillation efficiency of nuclear recoil in liquid xenon, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 449 (2000) 147. [69] F. Arneodo et al., Study of solar neutrinos with the 600 t liquid argon ICARUS detector, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 455 (2000) 376. [70] F. Arneodo et al., Determination of through-going tracks direction by means of δ-rays in the ICARUS liquid argon time projection chamber, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 449 (2000) 42. [71] M. Aglietta et al., Search for high energy GRBs with EASTOP, Astronomy and Astrophysics Supplement 138 (1999) 595. [72] P. CENNINI et al., Detection of scintillation light in coincidence with ionizing tracks in a liquid argon time projection chamber, Nuclear Instruments and Methods in Physics Research Section A 432 (1999) 240. [73] E.T. Collaboration et al., Study of jet production in p-n interactions at s 500 GeV in EAS multicore events, Physics Letters B 460 (1999) 474. [74] F. Arneodo, Solar ν detection with the ICARUS experiment and the neutron background measurement., Nuclear Physics B 70 (1999) 458. [75] R.A. Falcone et al., The hadron calorimeter of EAS-TOP: operation, calibration and resolution., Nuclear Instruments and Methods in Physics Research 420 (1999) 117. [76] E.T. Collaboration et al., The EAS size spectrum and the cosmic ray energy spectrum in the region 10 15-10 16 ev, Astroparticle Physics 10 (1999) 1. [77] M. Aglietta et al., The cosmic ray anisotropy at E 0 > 100 TeV, Advances in Space Research 23 (1999) 603. 5
[78] F. Arneodo et al., Neutron background measurements in the Hall C of the Gran Sasso Laboratory, Nuovo cimento. A 112 (1999) 819. [79] M. Aglietta et al., The high energy muon spectrum in Extensive Air Showers: first data from LVD and EAS-TOP at Gran Sasso, Astroparticle Physics 9 (1998) 185. [80] F. Arneodo et al., Performance evaluation of a hit finding algorithm for the ICARUS detector., Nuclear Instruments and Methods in Physics Research 412 (1998) 440. [81] F. Arneodo et al., Calibration of BC501A liquid scintillator cells with monochromatic neutron beams, Nuclear Instruments & Methods In Physics Research Section A-Accelerators Spectrometers Detectors And Associated Equipment 418 (1998) 285. [82] M. Aglietta et al., Results on high-energy cosmic rays by EAS-TOP at Gran Sasso., Nuovo Cimento Della Societa Italiana Di Fisica C-Geophysics And Space Physics 20 (1997) 985. [83] M. Aglietta et al., Comparison of the electron and muon data in extensive air showers with the expectations from a cosmic-ray composition and hadron interaction model., Nuovo Cimento B 112 (1997) 139. [84] M. Aglietta et al., The shapes of the atmospheric Cherenkov light images from extensive air showers, Astroparticle Physics 6 (1997) 143. [85] E.T. Collaboration et al., A limit to the rate of ultra high energy gamma-rays in the primary cosmic radiation, Astroparticle Physics 6 (1996) 71. [86] M. Aglietta et al., A Measurement of the Solar and Sidereal Cosmic-Ray Anisotropy at E 0 10 14 ev, Astrophysical Journal v.470 470 (1996) 501. [87] M. Aglietta et al., Search for Gamma-Ray Bursts at Photon Energies E 10 GeV and E 80 TeV, Astrophysical Journal v.469 469 (1996) 305. [88] M. Aglietta et al., Search for chaotic features in the arrival times of air showers, EPL (Europhysics Letters) 34 (1996) 231. [89] M. Aglietta et al., Large P T physics with cosmic-ray events, Il Nuovo Cimento C 18 (1995) 663. [90] M. Aglietta et al., Results on candidate UHE gamma-ray sources by the EAS-TOP array (1989-1993), Astroparticle Physics 3 (1995) 1. [91] F. Arneodo, VHE Observations of the Crab Nebula from the Cherenkov array of EAS-TOP, (1995). [92] M. Aglietta et al., Study of the primary cosmic ray composition around the knee of the energy spectrum, Physics Letters B 337 (1994) 376. [93] M. Aglietta et al., The limit to the UHE extraterrestrial neutrino flux from the observations of horizontal air showers at EAS-TOP, Physics Letters B 333 (1994) 555. [94] M. Aglietta et al., UHE cosmic ray event reconstruction by the electromagnetic detector of EAS-TOP, Nuclear Instruments and Methods in Physics Research Section A 336 (1993) 310. 6
[95] M. Aglietta et al., Fractal behavior of cosmic ray time series - Chaos or stochasticity?, Journal of Geophysical Research (ISSN 0148-0227) 98 (1993) 15241. [96] M. Aglietta et al., First observation of high energy cosmic ray events obtained in coincidence between EAS-TOP and LVD at Gran Sasso, Nuovo cimento. A 105 (1993) 1815. [97] M. Aglietta et al., The EAS-TOP calorimeter, Nuovo Cimento Della Societa Italiana Di Fisica C-Geophysics And Space Physics 15 (1992) 735. [98] M. Aglietta et al., Search for 100 TeV gamma-ray emission from the Galactic disk, Astrophysical Journal 397 (1992) 148. [99] M. Aglietta et al., EAS-TOP: Results of the gamma-ray astronomy at 10 14 ev, Il Nuovo Cimento C 15 (1992) 723. [100] M. Aglietta et al., EAS-TOP: Lateral and temporal characteristics of extensive air showers, Il Nuovo Cimento C 15 (1992) 713. [101] M. Aglietta et al., Imaging of atmospheric EAS Cherenkov light at EAS-TOP, Il Nuovo Cimento C 15 (1992) 357. [102] M. Aglietta et al., Search for cosmic γ-ray bursts in the (1-50) GeV energy range, Il Nuovo Cimento C 15 (1992) 441. [103] M. Aglietta et al., EAS Cherenkov at Gran Sasso: correlated observations at the surface and with deep underground events, Il Nuovo Cimento A Series 11 105 (1992) 1806. [104] R. Bellotti et al., Simultaneous observation of extensive air showers and deep-underground muons at the Gran Sasso Laboratory., Physical Review D 42 (1990) 1396. 7