Imperial College London, UK.
Philos Trans A Math Phys Eng Sci. 2012 Feb 28;370(1961):876-91. doi: 10.1098/rsta.2011.0459.
The ATLAS and CMS experiments at the CERN Large Hadron Collider are discovery experiments. Thus, the aim was to make them sensitive to the widest possible range of new physics. New physics is likely to reveal itself in addressing questions such as: how do particles acquire mass; what is the particle responsible for dark matter; what is the path towards unification; do we live in a world with more space-time dimensions than the familiar four? The detection of the Higgs boson, conjectured to give mass to particles, was chosen as a benchmark to test the performance of the proposed experiment designs. Higgs production is one of the most demanding hypothesized processes in terms of required detector resolution and background discrimination. ATLAS and CMS feature full coverage, 4π-detectors to measure precisely the energies, directions and identity of all the particles produced in proton-proton collisions. Realizing this goal has required the collaborative efforts of enormous teams of people from around the world.
欧洲核子研究中心大型强子对撞机上的 ATLAS 和 CMS 实验是探索性实验。因此,其目的是使它们对尽可能广泛的新物理现象敏感。新物理很可能通过解决以下问题来揭示自身:粒子如何获得质量;负责暗物质的粒子是什么;通往统一的道路是什么;我们生活在一个拥有比熟悉的四个维度更多的时空维度的世界中吗?希格斯玻色子的探测被选为测试所提出的实验设计性能的基准,希格斯玻色子被推测为赋予粒子质量。希格斯产生是根据所需探测器分辨率和背景辨别能力来要求的最苛刻的假设过程之一。ATLAS 和 CMS 具有全面覆盖的 4π探测器,可以精确测量质子-质子碰撞中产生的所有粒子的能量、方向和特性。实现这一目标需要来自世界各地的庞大团队的协作努力。
