The Experimental Study of Particle Interactions at High Energy
Lead Research Organisation:
University of Cambridge
Department Name: Physics
Abstract
The Cambridge High Energy Physics Group focuses its research activities on experiments at high-energy accelerators, currently the Large Hadron Collider and the ATLAS and LHCb experiments at CERN, the neutrino experiment MicroBooNE, and the long-baseline neutrino experiment DUNE at Fermilab, and future collider facilities. The goal is to understand the fundamental particles of nature and their interactions, in particular, to discover physics beyond our current understanding, to understand why the Universe is made only of matter and not antimatter and to reveal the identity of dark matter.
The Group is also central to the multi-disciplinary Quantum Technologies for Fundamental Physics projects, AION and MAGIS, which use novel atom interferometry to detect and identify sources of dark matter and gravitational waves in the Universe.
This grant will enable the group to fully exploit the physics of the LHC, to deliver our commitments to the current upgrades of the ATLAS and LHCb experiments, to prepare for the future upgrades of ATLAS and LHCb, to consolidate our strong participation in our neutrino programme, to deliver our commitments and exploit the first physics from the AION project and MAGIS experiment, and to undertake generic hardware research and development. The opportunities offered by this exciting physics programme will not only drive the forefront of discovery, but also provide substantial impact to local enterprises and on public engagement.
The Group is also central to the multi-disciplinary Quantum Technologies for Fundamental Physics projects, AION and MAGIS, which use novel atom interferometry to detect and identify sources of dark matter and gravitational waves in the Universe.
This grant will enable the group to fully exploit the physics of the LHC, to deliver our commitments to the current upgrades of the ATLAS and LHCb experiments, to prepare for the future upgrades of ATLAS and LHCb, to consolidate our strong participation in our neutrino programme, to deliver our commitments and exploit the first physics from the AION project and MAGIS experiment, and to undertake generic hardware research and development. The opportunities offered by this exciting physics programme will not only drive the forefront of discovery, but also provide substantial impact to local enterprises and on public engagement.
Organisations
Publications
Alonso I
(2022)
Cold atoms in space: community workshop summary and proposed road-map
in EPJ Quantum Technology
Mitchell J
(2022)
MAGIS-100 environmental characterization and noise analysis
in Journal of Instrumentation
Calabrese R
(2022)
Performance of the LHCb RICH detectors during LHC Run 2
in Journal of Instrumentation
Aaij R
(2023)
Measurement of the mass difference and relative production rate of the O b - and ? b - baryons
in Physical Review D
Aaij R
(2023)
A study of $$C\!P$$ violation in the decays $${ {B} ^\pm } \rightarrow [{ {K} ^+} { {K} ^-} { {\uppi } ^+} { {\uppi } ^-} ]_{D} h^{\pm }$$ ($$h = K, \pi $$) and $${ {B} ^\pm } \rightarrow [{ {\uppi } ^+} { {\uppi } ^-} { {\uppi } ^+} { {\uppi } ^-} ]_{D} h^{\pm }$$
in The European Physical Journal C
Aaij R
(2023)
Measurement of the ?_{b}^{0}??(1520)µ^{+}µ^{-} Differential Branching Fraction.
in Physical review letters
Aaij R
(2023)
Test of lepton flavor universality using B 0 ? D * - t + ? t decays with hadronic t channels
in Physical Review D
Cojocariu L
(2023)
A multi-channel TDC-in-FPGA with 150 ps bins for time-resolved readout of Cherenkov photons
in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Aaij R
(2023)
Evidence of a J / ? K S 0 Structure in B 0 ? J / ? ? K S 0 Decays
in Physical Review Letters
Aaij R
(2023)
Observation of New O_{c}^{0} States Decaying to the ?_{c}^{+}K^{-} Final State.
in Physical review letters