LIVERPOOL REQUEST FOR POSTDOCTORAL RESEARCH ASSISTANTS 2022
Lead Research Organisation:
University of Liverpool
Department Name: Physics
Abstract
Fundamental physics strives to answer the big questions: what is our Universe made of; how did it evolve; what forces govern it and how do they shape the phenomena we observe? In particle physics we build experiments to examine the very smallest constituents of the Universe, fundamental particles, so that we can address these questions with our findings.
Our knowledge of how fundamental particles behave is encapsulated in a theory called the Standard Model. It has enormous predictive power and provides a simple framework to understand the nature of the Universe. However, we also know the theory is incomplete. Experiments at the highest energies let us test predictions and determine the limits of the validity of our theory. Dedicated high-precision experiments let us probe predictions to incredible levels of accuracy. The faintest trace of any disagreement between theory and experimental data could provide the first hint of new laws of physics
operating, which would be a step forward in understanding the nature of the Universe.
One of the most pressing questions we have concerns why matter dominates so much over anti-matter. Matter and antimatter should have been created in equal quantities in the early Universe, but very little anti-matter can be observed now. This defining feature of our Universe must ultimately be due to a difference in behaviour between matter and anti-matter, but this difference is a mystery. Neutrinos, the most elusive of particles, may hold the key to understanding why this happened. They have no charge, barely interact with matter, have a very small mass and to detect them we have had to
build enormous but very sensitive detectors. An important part of our research is to make detailed measurements of neutrinos, to understand their masses and whether they are responsible for our matter-dominated universe.
Another mystery we seek to resolve concerns dark matter. We know that there are not enough stars visible in galaxies to explain the speed at which stars rotate around them. We explain this by hypothesizing that galaxies also contain invisible (dark) matter. Dark matter supplies the extra gravitational force necessary to keep stars in their orbits, but its nature is unknown. Many explanations have been proposed, ranging from it being formed of extremely low mass particles to massive black holes. Some explanations have been excluded, but many are extremely challenging to either confirm or
reject experimentally. To address this, we develop more powerful experiments using a wide range of approaches and technologies, to perform the broadest search for the unknown particles that may form this elusive dark matter.
Our knowledge of how fundamental particles behave is encapsulated in a theory called the Standard Model. It has enormous predictive power and provides a simple framework to understand the nature of the Universe. However, we also know the theory is incomplete. Experiments at the highest energies let us test predictions and determine the limits of the validity of our theory. Dedicated high-precision experiments let us probe predictions to incredible levels of accuracy. The faintest trace of any disagreement between theory and experimental data could provide the first hint of new laws of physics
operating, which would be a step forward in understanding the nature of the Universe.
One of the most pressing questions we have concerns why matter dominates so much over anti-matter. Matter and antimatter should have been created in equal quantities in the early Universe, but very little anti-matter can be observed now. This defining feature of our Universe must ultimately be due to a difference in behaviour between matter and anti-matter, but this difference is a mystery. Neutrinos, the most elusive of particles, may hold the key to understanding why this happened. They have no charge, barely interact with matter, have a very small mass and to detect them we have had to
build enormous but very sensitive detectors. An important part of our research is to make detailed measurements of neutrinos, to understand their masses and whether they are responsible for our matter-dominated universe.
Another mystery we seek to resolve concerns dark matter. We know that there are not enough stars visible in galaxies to explain the speed at which stars rotate around them. We explain this by hypothesizing that galaxies also contain invisible (dark) matter. Dark matter supplies the extra gravitational force necessary to keep stars in their orbits, but its nature is unknown. Many explanations have been proposed, ranging from it being formed of extremely low mass particles to massive black holes. Some explanations have been excluded, but many are extremely challenging to either confirm or
reject experimentally. To address this, we develop more powerful experiments using a wide range of approaches and technologies, to perform the broadest search for the unknown particles that may form this elusive dark matter.
Organisations
Publications
Aad G
(2024)
Search for the decay of the Higgs boson to a Z boson and a light pseudoscalar particle decaying to two photons
in Physics Letters B
Aad G
(2024)
Observation of W?? triboson production in proton-proton collisions at s = 13 TeV with the ATLAS detector
in Physics Letters B
Aad G
(2024)
Electron and photon energy calibration with the ATLAS detector using LHC Run 2 data
in Journal of Instrumentation
Aad G
(2024)
Evidence for the Higgs Boson Decay to a Z Boson and a Photon at the LHC.
in Physical review letters
Aad G
(2024)
Measurement of the Centrality Dependence of the Dijet Yield in p + Pb Collisions at s NN = 8.16 TeV with the ATLAS Detector
in Physical Review Letters
Aad G
(2024)
Search for the Z? decay mode of new high-mass resonances in pp collisions at s = 13 TeV with the ATLAS detector
in Physics Letters B
Aad G
(2024)
Search for non-resonant production of semi-visible jets using Run 2 data in ATLAS
in Physics Letters B
Aad G
(2024)
Performance and calibration of quark/gluon-jet taggers using 140 fb -1 of pp collisions at TeV with the ATLAS detector*
in Chinese Physics C
Aad G
(2024)
Observation of W Z ? Production in p p Collisions at s = 13 TeV with the ATLAS Detector
in Physical Review Letters