Abstract
We present a first proof of concept to directly use neural network based pattern recognition to trigger on distinct calorimeter signatures from displaced particles, such as those that arise from the decays of exotic long-lived particles. The study is performed for a high granularity forward calorimeter similar to the planned high granularity calorimeter for the high luminosity upgrade of the CMS detector at the CERN Large Hadron Collider. Without assuming a particular model that predicts long-lived particles, we show that a simple convolutional neural network, that could in principle be deployed on dedicated fast hardware, can efficiently identify showers from displaced particles down to low energies while providing a low trigger rate.
Highlights
The first proof of concept of using pattern recognition with fast convolutional neural networks to trigger on displaced calorimeter signatures is presented
Displaced signatures in a forward calorimeter can be identified with good efficiency and low background rate
This study indicates a potential increase in sensitivity to low mass, forward-moving long-lived particles
Summary
The endcap calorimeter is built using Geant4 [30] and is placed at z = 3 m distance to the interaction point It covers a pseudorapidity (η) between 1.5 and 3.0, has a depth of 34 cm, and consists of 14 equidistant layers. The sensors are placed in 30 rings in η, each containing 120 segments in φ, leading to 50 400 sensors in total, each with a size of approximately 0.05 in η and φ. This configuration corresponds to approximately 60 radiations lengths, and covers electromagnetic showers only. The rotation with respect to the projection axis is randomly sampled, but constrained such that at least the first and the last layer of the calorimeter are hit. The total rate is calculated by normalising the minimum bias events by the LHC revolution frequency of 11 246 Hz and the number of bunches of 2760 [32]
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