| The Pamela silicon tungsten calorimeter | p. 3 |
| Design and development of a dense, fine grained silicon tungsten calorimeter with integrated electronics | p. 10 |
| High resolution silicon detector for 1.2-3.1 eV (400-1000 nm) photons | p. 19 |
| The electromagnetic calorimeter of the Hera-b experiment | p. 27 |
| The status of the ATLAS tile calorimeter | p. 33 |
| Design and mass production of scintillator pad detector (SPD) / preshower (PS) detector for LHC-b experiment | p. 43 |
| Study of new FNAL-NICADD extruded scintillator as active media of large EMCal of ALICE at LHC | p. 49 |
| Test beam study of the KOPIO Shashlyk calorimeter prototype | p. 55 |
| The Shashlik electro-magnetic calorimeter for the LHCb experiment | p. 61 |
| Quality of mass produced lead-tungstate crystals | p. 71 |
| Status of the CMS electromagnetic calorimeter | p. 83 |
| Scintillation detectors for radiation-hard electromagnetic calorimeters | p. 93 |
| Energy, timing and two-photon invariant mass resolution of a 256-channel PBWO[subscript 4] calorimeter | p. 103 |
| A high performance hybrid electromagnetic calorimeter at Jefferson Lab | p. 109 |
| The crystal ball and TAPS detectors at the MAMI electron beam facility | p. 116 |
| Front-end electronics of the ATLAS tile calorimeter | p. 127 |
| The ATLAS tilecal detector control system | p. 135 |
| Performance of the liquid argon final calibration board | p. 143 |
| Overview of the LHCb calorimeter electronics | p. 151 |
| LHCb preshower photodetector and electronics | p. 156 |
| The CMS ECAL readout architecture and the clock and control system | p. 162 |
| Test of the CMS-ECAL trigger primitive generation | p. 173 |
| CMS ECAL off-detector electronics | p. 181 |
| Performance of a low noise readout ASIC for the W-Si calorimeter physics prototype for the future linear collider | p. 191 |
| Properties of a sampling calorimeter with warm-liquid ionization chambers | p. 199 |
| Data quality monitoring for the DO calorimeter | p. 205 |
| Status of the construction of the ATLAS electromagnetic liquid argon calorimeter, overview of beam test performance studies | p. 210 |
| Uniformity of response of ATLAS liquid argon EM calorimeter | p. 218 |
| Status of the ATLAS liquid argon hadronic endcap calorimeter construction | p. 225 |
| Results from particle beam tests of the ATLAS liquid argon endcap calorimeters | p. 231 |
| First results of the DREAM project | p. 241 |
| Electron and muon detection with a dual-readout (DREAM) calorimeter | p. 258 |
| The neutron zero degree calorimeter for the ALICE experiment | p. 274 |
| The liquid xenon scintillation calorimeter of the MEG experiment : operation of a large prototype | p. 281 |
| Detection of high energy particles using radio frequency signals | p. 287 |
| Hadronic shower simulation | p. 295 |
| E.M. and hadronic shower simulation with FLUKA | p. 303 |
| Simulation of the LHCb electromagnetic calorimeter response with GEANT4 | p. 309 |
| Comparison of beam test results of the combined ATLAS liquid argon endcap calorimeters with GEANT3 and GEANT4 simulations | p. 314 |
| GEANT4 hadronic physics validation with LHC test-beam data | p. 321 |
| The full simulation of the GLAST LAT high energy gamma ray telescope | p. 329 |
| Response of the KLOE electromagnetic calorimeter to low-energy particles | p. 337 |
| Calorimeter algorithms for DO | p. 343 |
| Identification of low P[subscript T] muon with the ATLAS tile calorimeter | p. 349 |
| Electron and photon reconstruction with fully simulated events in the CMS experiment | p. 355 |
| Expected performance of Jet, [tau] and E[subscript T] reconstruction in ATLAS | p. 362 |
| LHCb calorimeter from trigger to physics | p. 368 |
| The calibration strategy of CMS electromagnetic calorimeter | p. 377 |
| Energy and impact point reconstruction in the CMS ECAL (testbeam results from 2003) | p. 386 |
| Precision linearity studies of the ATLAS liquid argon EM calorimeter | p. 391 |
| Calibration of the ATLAS tile calorimeter | p. 398 |
| Performance of the CMS ECAL laser monitoring source in the test beam | p. 404 |
| Energy reconstruction algorithms and their influence on the ATLAS tile calorimeter | p. 411 |
| Study of the biological effectiveness of ionizing radiations for a more realistic evaluation of the radiation quality in hadrontherapy | p. 421 |
| New dosimetry technologies for IMRT (intensity modulated radio therapy) | p. 423 |
| Performance goals and design considerations for a linear collider calorimeter | p. 435 |
| Improving the jet reconstruction with the particle flow method; an introduction | p. 445 |
| Fine grained SiW ECAL for a linear collider detector | |
| Silicon-tungsten sampling electromagnetic calorimeter for the TeV electron-positron linear collider | p. 452 |
| LCCAL : a calorimeter prototype for future linear colliders | p. 462 |
| Analog vs. digital hadron calorimetry at a future electron-positron linear collider | p. 468 |
| Very low background scintillators in DAMA project : results and perspectives | p. 477 |
| Review of massive underground detectors | p. 485 |
| The fluorescence detector of the Pierre Auger observatory | p. 507 |
| The EUSO mission for the observation of ultra high energy cosmic rays from space | p. 520 |
| Performance of a 3D imaging electromagnetic calorimeter for the AMS02 space experiment | p. 526 |
| Beam test calibration of the balloon borne imaging calorimeter for the CREAM experiment | p. 532 |
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