Enhancing Long-Lived Particles Searches at the LHC with Precision Timing Information

We explore the physics potential of using precision timing information at the LHC in searches for long-lived particles (LLPs). In comparison with the light standard model particles, the decay products of massive LLPs arrive at detectors with time delays around the nanosecond scale. We propose new st...

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Bibliographic Details
Published in:Physical review letters 2019-04, Vol.122 (13), p.131801-131801, Article 131801
Main Authors: Liu, Jia, Liu, Zhen, Wang, Lian-Tao
Format: Article
Language:English
Subjects:
Dependence
Fermions
Higgs bosons
Large Hadron Collider
Pair production
Particle decay
PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
Quarks
Searching
Standard model (particle physics)
Supersymmetry
Time lag
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Summary:We explore the physics potential of using precision timing information at the LHC in searches for long-lived particles (LLPs). In comparison with the light standard model particles, the decay products of massive LLPs arrive at detectors with time delays around the nanosecond scale. We propose new strategies to take advantage of this time delay feature by using initial state radiation to time stamp the collision event and require at least one LLP to decay within the detector. This search strategy is effective for a broad range of models. In addition to outlining this general approach, we demonstrate its effectiveness with the projected reach for two benchmark scenarios: a Higgs boson decaying into a pair of LLPs, and pair production of long-lived neutralinos in the gauge mediated supersymmetry breaking models. Our strategy increases the sensitivity to the lifetime of the LLP by two orders of magnitude or more and particularly exhibits a better behavior with a linear dependence on the lifetime in the large lifetime region compared to traditional LLP searches. The timing information significantly reduces the standard model background and provides a powerful new dimension for LLP searches.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.122.131801