SiD Linear Collider Detector R&D, DOE Final Report | |
Brau, James E.1  Demarteau, Marcel2  | |
[1] Univ. of Oregon, Eugene, OR (United States);Argonne National Lab. (ANL), Argonne, IL (United States) | |
关键词: Particle Physics; Particle Detectors; Linear Collider; | |
DOI : 10.2172/1182602 RP-ID : DOE-SiD--0001476 PID : OSTI ID: 1182602 |
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学科分类:物理(综合) | |
美国|英语 | |
来源: SciTech Connect | |
【 摘 要 】
The Department of Energy???s Office of High Energy Physics supported the SiD university detector R&D projects in FY10, FY11, and FY12 with no-cost extensions through February, 2015. The R&D projects were designed to advance the SiD capabilities to address the fundamental questions of particle physics at the International Linear Collider (ILC): ??? What is the mechanism responsible for electroweak symmetry breaking and the generation of mass? ??? How do the forces unify? ??? Does the structure of space-time at small distances show evidence for extra dimensions? ??? What are the connections between the fundamental particles and forces and cosmology? Silicon detectors are used extensively in SiD and are well-matched to the challenges presented by ILC physics and the ILC machine environment. They are fast, robust against machine-induced background, and capable of very fine segmentation. SiD is based on silicon tracking and silicon-tungsten sampling calorimetry, complemented by powerful pixel vertex detection, and outer hadronic calorimetry and muon detection. Radiation hard forward detectors which can be read out pulse by pulse are required. Advanced calorimetry based on a particle flow algorithm (PFA) provides excellent jet energy resolution. The 5 Tesla solenoid is outside the calorimeter to improve energy resolution. PFA calorimetry requires fine granularity for both electromagnetic and hadronic calorimeters, leading naturally to finely segmented silicon-tungsten electromagnetic calorimetry. Since silicon-tungsten calorimetry is expensive, the detector architecture is compact. Precise tracking is achieved with the large magnetic field and high precision silicon microstrips. An ancillary benefit of the large magnetic field is better control of the e???e??? pair backgrounds, permitting a smaller radius beampipe and improved impact parameter resolution. Finally, SiD is designed with a cost constraint in mind. Significant advances and new capabilities have been made and are described in this report.
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