CONTENTS -- Preface -- Introduction -- Historical Review of Calorimeter Developments K. Pretzl -- 1. Introduction -- 2. Early Developments -- 3. Segmented Calorimeters -- 4. Segmentation Using Wavelength Shifter Read-out -- 5. Liquid Ionization Chambers -- 6. Compensating Calorimeters -- 7. Other Sampling Calorimeters -- 8. Crystal Calorimeters -- 9. Cryogenic Calorimeters -- 10. Detection of Extraterrestrial Neutrinos -- 11. The Atmosphere as Calorimeter -- 12. Conclusions -- Acknowledgments -- References -- Overview and Status of Calorimetry at LHC D. Fournier -- 1. Introduction -- 2. EM Calorimetry -- 2.1. ATLAS EM Calorimetry -- 2.1.1. Main features of the design -- 2.1.2. Difficulties with engineering and fabrication -- 2.1.3. Test beam results -- 2.2. CMS EM calorimetry -- 2.2.1. Main features of the design and evolution since TDR -- 2.2.2. Readout and noise -- 2.2.3. Short term follow-up of light output -- 2.3. System aspects -- 2.3.1. Effect of tracker material and magnetic field -- 2.3.2. Calibration in situ -- 2.3.3. Constant term -- 2.3.4. Use of granularity -- 2.3.5. Linearity -- 2.3.6. Data reduction -- 3. Hadronic Calorimetry -- 3.1. CMS hadronic Calorimeter -- 3.2. ATLAS Tile Calorimeter -- 3.3. ATLAS Hadronic End-Cap -- 3.4. Resolution, linearity -- 3.5. In situ Calibration -- 3.6. Some illustrations -- 4. Forward Calorimetry -- 4.1. A harsh region -- 4.2. The CMS Hadronic Forward Calorimeter -- 4.3. The ATLAS FCAL -- 4.4. Forward jet tagging -- 5 . Status of Construction -- 5.1. Construction advancement -- 5.2. Staging plans -- 6. Calorimetry in LHCb -- 6.1. General strategy -- 6.2. LHCb layout -- 6.3. Some performances -- 6.4. A WOTTY: scintillator damage by radiations -- 7. Calorimetry in ALICE -- 7.1. Photons at large angle -- 7.2. Zen, degree calorimeters -- 8. Summary -- Acknowledgements -- References.

Calorimetry in Astrophysics S. P. Swordy -- 1. Introduction -- 2. Direct Measurements -- 3. Effects of Energy Resolution -- 4. Atmospheric Calorimetry -- 4.1. Particle Sampling -- 4.2. Cherenkov Detection -- 4.3. Air Fluorescence -- 4.4. Air Shower Results -- 5. Other Techniques -- 6. Summary -- References -- Considerations for Calorimetry at a Super B Factory W. Wisniewski (contribution not received) -- Calorimeter Considerations for a Linear Collider Detector R. E. Frey -- 1. Introduction -- 2. Physics Requirements -- 3. The LC Environment -- 3.1. The IP and IP Radiation -- 3.2. Bunch Timing -- 4. Making the Most of the Tracker: The Energy Flow Method -- 4.1. Segmentation Requirement -- 4.2. Requirements for the Electromagnetic Calorimeter -- 4.3. Requirements for the Hadmnic Calorimeter -- 4.4. Limits to Jet Resolution -- 5 . Design Ideas -- 5.1. TESLA -- 5.2. JLC Detector -- 5.3. SD and LD -- 6. Prospects -- Acknowledgements -- References -- Calorimetry Design with Energy-Flow Concept (Imaging Detector for High-Energy Physics) V. L. Morgunov -- 1. Introduction -- 2. Combined Energy-Flow, Main Idea -- 3. Combined Energy-Flow, Energy Resolution Limit -- 4. Combined Energy-Flow, Reconstruction Algorithm -- 5. From IP to Calorimeter in detail -- Requirements for tracker and reconstruction: -- Requirements for absorber material and sampling structure: Electromagnetic part: -- Hadronic part: -- Requirements on the electronic cell sizes -- Electromagnetic part: -- Hadronic part: -- 6. Compensation and Combined Energy-Flow -- Requirements on the imaging calorimeter energy resolution: -- Compensation: -- 7. Combined Energy-Flow, Realization -- References -- Calorimetry in Astrophysics -- Covener's Report T. Parnell -- ATIC, a Balloon Borne Calorimeter for Cosmic Ray Measurements J. Isbert et al. -- 1. The ATIC design -- 1.1. Limitations.

1.2. The ATIC instrument -- 1.3. The Target Module -- 1.4. The Calorimeter -- 2. The ATIC Trigger -- 3. Read out and control -- 4. Summary -- References -- ATIC Backscatter Study Using Monte Carlo Methods in FLUKA & ROOT T. Wilson et al. -- 1. Introduction -- 2. Benchmarking and Testing FLUKA -- 3. The Geometry Conversion Technique -- 4. Brief Description of the Instrument Geometry Studied -- 5. Resultant Backscatter Albedoes -- 6. Conclusions -- References -- A Silicon-Tungsten Calorimeter for Cosmic-Ray Physics V. Bonvicini et al. -- 1. Introduction: the PAMELA experiment -- 2. Design characteristics of the PAMELA Imaging Calorimeter -- 3. Simulated performance. -- 4. Beam test results -- 5 . Self-triggering operation of the calorimeter -- 6. Conclusion -- References -- Electromagnetic Calorimeter for the AMS-02 Experiment R. Kossakowski et al. -- 1. Introduction -- 2. Photomultiplier and its front end electronics -- 3. Magnetic shielding and light collection system -- 4. Conclusions -- References -- Performances of the AMS-02 Electromagnetic Calorimeter P. Maestro et al. -- 1. Introduction -- 2. The electromagnetic calorimeter for AMS-02 -- 3. Test beam setup -- 4. Test beam data analysis -- 4.1. Measurement of the effective sampling thickness -- 4.2. Energy linearity -- 4.3. Energy resolution -- 5. 3D shower imaging -- 6. Conclusions -- References -- The Status of GLAST CsI Calorimeter A . Chekhtman -- 1. Introduction -- 2. LAT technical description -- 3. Calorimeter design overview -- 4. Calorimeter status -- References -- Performance of GLAST Calorimeter R. Terrier et al. -- 1. Introduction -- 2. Calibration -- 3. Energy Measurement -- 3.1. Low energy regime -- 3.2. High energy regime -- 4. Position measurement -- 4.1. Longitudinal position reconstruction -- 4.2. Transverse position -- 5 . Conclusion -- References.

Cosmic Ray Energetics And Mass (CREAM): Calibrating a Cosmic Ray Calorimeter O. Ganel et al. -- 1. Introduction CREAM Science and measurement objectives -- 2. The CREAM Detector -- 3. Calibration -- 4. Beam Test Results -- 5. Conclusions -- Acknowledgments -- References -- VERITAS: A Next Generation Atmospheric Cherenkov Detector and Calorimeter for Gamma-Ray Astronomy F. Krennrich -- 1. Introduction -- 2. The VERITAS concept -- 2.1. Optics -- 2.2. Camera -- 2.3. Electronics -- 2.4. Performance of VERITAS: Simulations -- 3. Energy Reconstruction and Calibration -- 4. Conclusions -- Acknowledgments -- References -- Pierre Auger Observatory: The World's Largest Calorimeter A . K. Tripathi -- 1. Introduction -- 2. The Surface Detectors -- 3. The Air Fluorescence Detectors -- 4. Communication, DAQ and Triggering -- 5. Aperture and Event Rates -- 6. Calibration and Energy Resolution -- 7. Status of Auger -- 8. Summary -- References -- EUSO and OWL: Atmospheric Cosmic Ray Calorimetry from Space K. Arisaka (contribution not received) -- Calorimetry (GeV-EeV) in AMANDA and IceCube Neutrino Telescopes J. Lamoureux (contribution not received) -- Crystal Calorimetry -- Performance of a Small Angle BGO Calorimeter at BELLE H.-C. Huang -- 1. Introduction -- 2. Readout Electronics and DAQ -- 3. Trigger System -- 4. Calibration -- 5. Luminosity Measurement -- 5.1. IP Dependence -- 6. Two-photon Physics -- 7. Summary -- Acknowledgments -- References -- Performance and Calibration of the Crystal Calorimeter of the BaBar Detector M. Kocian -- 1. Introduction -- 2. Calorimetry goals -- 3. Layout and Assembly -- 3.1. General Overview -- 3.2. Mechanical Assembly -- 3.3. Crystal Assembly -- 4. Calibration -- 4.1. Overview -- 4.2. Individual Crystal Calibration -- 4.2.1. Radioactive Source Calibration -- 4.2.2. The Bhabha Calibration -- 4.3. Shower Energy Correction.

4.3.1. 0 Calibration -- 5 . Performance -- 5.1. 0 and 77 mass and width -- 5.2. Resolution -- 6. Summary -- References -- A Systematic Study of Radiation Damage to Large Crystals of CsI(T1) in the BaBar Detector T. Hryn'ova -- 1. Introduction -- 2. Sources of Radiation Damage -- 3. Dose Monitoring -- 3.1. RadFET Monitoring -- 3.2. Leakage Currents -- 4. Light Yield (LY) Monitoring -- 4.1. Source Measurements -- 4.2. Bhabha Measurements -- 5. Crystal Scanner Experiment -- 6. Conclusion -- Acknowledgments -- References -- Performance and Upgrade Plans of the BELLE Calorimeter B. A . Shwartz -- 1. Introduction -- 2. Calorimeter structure and main features -- 3. Calorimeter performance -- 4. Tolerance to the high background environment -- 5. Luminosity monitoring -- 6. Conclusion -- References -- Development of Yttrium Doped Lead Tungstate Crystal for Physics Applications Q. Deng et al. -- 1. Introduction -- 2. Crystal Growth -- 3. Crystal Properties -- 3.1. Emission -- 3.2. Transmittance and Birefringence -- 3.3. Light Output and Decay Kinetics -- 3.4. Light Output Degradation under Irradiation -- 3.5. Damage Recovery -- 3.6. Light Response Uniformity -- 3.7. Radiation Induced Color Centers -- 3.8. Stability -- 4. Summary -- Acknowledgments -- References -- Performance of PWO Crystal Detectors for a High Resolution Hybrid Electromagnetic Calorimeter at Jefferson Lab A. Gasparian -- 1. Introduction -- 2. Experimental Setup -- 3. Energy Resolution -- 4. Position Resolution -- 5 . Detector Response versus Radiation Dose Rate -- Acknowledgments -- References -- The PHOTON BALL at COSY R. Novotny et al. -- 1. Physics Motivation -- 2. The Detector Concept -- 2.1. Technical Constraints -- 2.2. The Detector Design -- 3. Research and Development -- 3.1. The Performance of PbW04 -- 3.1.1. The Response to High Energy Photons.

3.1.2. The Response to Charged Particles.