Consolidated Grant for the Centre for Particle Physics at Royal Holloway, University of London
Lead Research Organisation:
Royal Holloway University of London
Department Name: Physics
Abstract
Experimental particle physics addresses some of the fundamental
questions about the structure and behaviour of the Universe at the
level of the smallest particles of matter, the quarks and the leptons,
and the forces acting between them. We are exploring fundamental
properties of particles at the the Large Hadron Collider (LHC) and
also exploring the nature of dark matter and neutrinos by developing
and employing novel detection systems.
We are contributing to the continued operation of the ATLAS project at
the Large Hadron Collider at CERN. We have constructed and
commissioned electronic systems and the software that drives them.
From the beginning of data taking we have played a leading role in
searches for exotic particles, the 2012 discovery of the Higgs boson,
and studies of the properties of the heaviest particle discovered so far:
the top quark. We are heavily invested in the
upgrades to the ATLAS detector, which will allow for the collection of
large datasets, capable of probing even more fundamental
questions at the energy frontier.
Although there is ample indirect evidence for the existence of dark
matter as inferred from its gravitational interactions, it has not yet
been directly detected in terrestrial laboratories. Direct detection
experiments seek to observe dark matter scattering on target detector
nuclei. We explore these issues through a world-leading dark matter
search with the Lux-Zeplin detector which uses liquid xenon and with the
development of a large dark matter detector DarkSide-20k which
uses liquid argon. The group's expertise in high pressure TPCs is now being
utilised to carry out measurements relevant to the study of neutrinos
as part of the DUNE and Hyper-K experiments.
Using detection techniques similar to those of our dark matter research, we are also involved in the
the puzzle surrounding the matter anti-matter asymmetry in the Universe by
studying the elusive neutrino particle. We measure CP violation in the lepton sector
using the T2K long baseline neutrino experiment in Japan.
Our expertise in accelerator science will allow us to carry out
studies for the machine-detector interface for the High Luminosity LHC
and ILC. We will also expand the interactions between our
phenomenology group and the experimental Neutrino and Dark Matter
communities.
questions about the structure and behaviour of the Universe at the
level of the smallest particles of matter, the quarks and the leptons,
and the forces acting between them. We are exploring fundamental
properties of particles at the the Large Hadron Collider (LHC) and
also exploring the nature of dark matter and neutrinos by developing
and employing novel detection systems.
We are contributing to the continued operation of the ATLAS project at
the Large Hadron Collider at CERN. We have constructed and
commissioned electronic systems and the software that drives them.
From the beginning of data taking we have played a leading role in
searches for exotic particles, the 2012 discovery of the Higgs boson,
and studies of the properties of the heaviest particle discovered so far:
the top quark. We are heavily invested in the
upgrades to the ATLAS detector, which will allow for the collection of
large datasets, capable of probing even more fundamental
questions at the energy frontier.
Although there is ample indirect evidence for the existence of dark
matter as inferred from its gravitational interactions, it has not yet
been directly detected in terrestrial laboratories. Direct detection
experiments seek to observe dark matter scattering on target detector
nuclei. We explore these issues through a world-leading dark matter
search with the Lux-Zeplin detector which uses liquid xenon and with the
development of a large dark matter detector DarkSide-20k which
uses liquid argon. The group's expertise in high pressure TPCs is now being
utilised to carry out measurements relevant to the study of neutrinos
as part of the DUNE and Hyper-K experiments.
Using detection techniques similar to those of our dark matter research, we are also involved in the
the puzzle surrounding the matter anti-matter asymmetry in the Universe by
studying the elusive neutrino particle. We measure CP violation in the lepton sector
using the T2K long baseline neutrino experiment in Japan.
Our expertise in accelerator science will allow us to carry out
studies for the machine-detector interface for the High Luminosity LHC
and ILC. We will also expand the interactions between our
phenomenology group and the experimental Neutrino and Dark Matter
communities.
Publications
Aalbers J
(2023)
First Dark Matter Search Results from the LUX-ZEPLIN (LZ) Experiment
in Physical Review Letters
Abreu H
(2022)
The tracking detector of the FASER experiment
in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Abreu H
(2024)
Search for dark photons with the FASER detector at the LHC
in Physics Letters B
Abreu H
(2023)
First Direct Observation of Collider Neutrinos with FASER at the LHC.
in Physical review letters
Assmann Ralph
(2023)
BDSIM v1.7.0 developments for the modelling of accelerators and their environment
in JACoW
Assmann Ralph
(2023)
Start-to-end tracking of therapeutic ion beams in BDSIM
in JACoW
ATLAS Collaboration
(2023)
Performance studies of tracking-based triggering using a fast emulation
Bailey I
(2023)
Searching for wave-like dark matter with QSHS
in SciPost Physics Proceedings
Borga A
(2023)
The ATLAS Readout System for LHC Runs 2 and 3
in Journal of Instrumentation
Canonero E
(2023)
Higher-order asymptotic corrections and their application to the Gamma Variance Model
in The European Physical Journal C