South-Eastern Particle Theory Alliance Sussex - RHUL - UCL 2020-2023 - UCL Node
Lead Research Organisation:
University College London
Department Name: Physics and Astronomy
Abstract
The proposed research joins scientists of the particle theory groups at Sussex, Royal Holloway and University College London in the hunt for new physics under four broad headings:
Collider and low-energy phenomenology:
The Large Hadron Collider boosts elementary particles to velocities so close to that of light that their effective mass grows by a factor of a billion. By smashing these particles together there are new discoveries to be made, and new theories of physics to test. We will work on the complex task of relating the debris of these collisions to the new models put forward by theorists to explain some of the most puzzling questions of the universe - what is the origin of mass? and is there a quantum theory of gravity?
Particle astrophysics and cosmology:
One of the most active areas of research in the past decade has been at the interface between particle physics and cosmology. In order to understand the history of the Universe we must understand physical laws in the first moments of the Big Bang, when temperatures and particle energies were huge. Conversely, by detailed observations of the universe today we can trace back the conditions and make deductions about physical laws at high energies. Our research will tackle big questions about the universe: why is there more matter than antimatter? what is the nature of neutrinos and dark matter? can we use gravitational waves to look at the first picoseconds of the Universe? how can the new quantum technology be used to search for dark matter and other invisible particles? and how can quantum theory and gravity be combined, and can we see their joint effects in the cosmos?
Fixed points of quantum field theory:
The recent discovery that Standard Model-like theories can be fundamental and predictive up to highest energies without being asymptotically free has opened a door into uncharted territory. These novel theories offer alternative ways to UV complete the Standard Model and to address its open challenges from an entirely new angle. Our research will focus on the systematic evaluation of these new types of theories, including the construction of benchmark models beyond the Standard Model. We combine these studies with our continuing quest towards a quantum version of general relativity. Predictions of these scenarios will be contrasted with data from particle colliders and cosmology.
Tools for high energy physics:
The high-luminosity LHC (HL-LHC) was announced as top priority of the European Strategy for Particle Physics and will dominate collider physics in the next decade. The aim of this science area is to improve tools for phenomenologically relevant BSM scenarios so that they meet the needs of the HL-LHC.
Collider and low-energy phenomenology:
The Large Hadron Collider boosts elementary particles to velocities so close to that of light that their effective mass grows by a factor of a billion. By smashing these particles together there are new discoveries to be made, and new theories of physics to test. We will work on the complex task of relating the debris of these collisions to the new models put forward by theorists to explain some of the most puzzling questions of the universe - what is the origin of mass? and is there a quantum theory of gravity?
Particle astrophysics and cosmology:
One of the most active areas of research in the past decade has been at the interface between particle physics and cosmology. In order to understand the history of the Universe we must understand physical laws in the first moments of the Big Bang, when temperatures and particle energies were huge. Conversely, by detailed observations of the universe today we can trace back the conditions and make deductions about physical laws at high energies. Our research will tackle big questions about the universe: why is there more matter than antimatter? what is the nature of neutrinos and dark matter? can we use gravitational waves to look at the first picoseconds of the Universe? how can the new quantum technology be used to search for dark matter and other invisible particles? and how can quantum theory and gravity be combined, and can we see their joint effects in the cosmos?
Fixed points of quantum field theory:
The recent discovery that Standard Model-like theories can be fundamental and predictive up to highest energies without being asymptotically free has opened a door into uncharted territory. These novel theories offer alternative ways to UV complete the Standard Model and to address its open challenges from an entirely new angle. Our research will focus on the systematic evaluation of these new types of theories, including the construction of benchmark models beyond the Standard Model. We combine these studies with our continuing quest towards a quantum version of general relativity. Predictions of these scenarios will be contrasted with data from particle colliders and cosmology.
Tools for high energy physics:
The high-luminosity LHC (HL-LHC) was announced as top priority of the European Strategy for Particle Physics and will dominate collider physics in the next decade. The aim of this science area is to improve tools for phenomenologically relevant BSM scenarios so that they meet the needs of the HL-LHC.
Planned Impact
The main beneficiaries of the research of our consortium outside academia will be business and industry, the education sector, school students, and the general public. The benefits will be delivered by outreach activities, by the training of highly skilled PhD students and post-docs, and by the exploration of opportunities for industrial engagement arising from the development of software tools for theoretical particle physics.
For schools and colleges we will develop activities and tools enriching students' understanding of the framework underpinning the Standard Model of particle physics. We will deliver them as part of our universities' physics outreach programme. We will also deliver talks on the research in this proposal both on and off campus.
For the general public we will disseminate our research through social media and public science events such as Nerd Nite. We will also seek to influence future decision makers amongst Arts and Humanities undergraduates through the Sussex module From Quarks to the Cosmos.
Business and the education sector will benefit from the rigorous scientific training we provide to the young researchers working with us on the research programme.
We will help students and postdocs wanting to make the transition out of academia with careers resources at department, university, and regional level.
We will also seek industrial partners for spin-offs from software we are developing, using our universities' structures supporting knowledge exchange.
For schools and colleges we will develop activities and tools enriching students' understanding of the framework underpinning the Standard Model of particle physics. We will deliver them as part of our universities' physics outreach programme. We will also deliver talks on the research in this proposal both on and off campus.
For the general public we will disseminate our research through social media and public science events such as Nerd Nite. We will also seek to influence future decision makers amongst Arts and Humanities undergraduates through the Sussex module From Quarks to the Cosmos.
Business and the education sector will benefit from the rigorous scientific training we provide to the young researchers working with us on the research programme.
We will help students and postdocs wanting to make the transition out of academia with careers resources at department, university, and regional level.
We will also seek industrial partners for spin-offs from software we are developing, using our universities' structures supporting knowledge exchange.
Organisations
People |
ORCID iD |
Frank Deppisch (Principal Investigator) |
Publications
Aalbers J
(2022)
A next-generation liquid xenon observatory for dark matter and neutrino physics
in Journal of Physics G: Nuclear and Particle Physics
Abdullahi A
(2023)
The present and future status of heavy neutral leptons
in Journal of Physics G: Nuclear and Particle Physics
Agostini Matteo
(2023)
Probing the mechanism of neutrinoless double-beta decay in multiple isotopes
in JHEP
Alimena J
(2020)
Searching for long-lived particles beyond the Standard Model at the Large Hadron Collider
in Journal of Physics G: Nuclear and Particle Physics
Antel C
(2023)
Feebly-interacting particles: FIPs 2022 Workshop Report
in The European Physical Journal C
Bolton P
(2021)
Two-neutrino double beta decay with sterile neutrinos
in Physical Review D
Bolton P
(2022)
Neutrinoless double beta decay via light neutralinos in R-parity violating supersymmetry
in Journal of High Energy Physics
Studentship Projects
Project Reference | Relationship | Related To | Start | End | Student Name |
---|---|---|---|---|---|
ST/T000880/1 | 01/10/2020 | 31/03/2024 | |||
2766019 | Studentship | ST/T000880/1 | 28/09/2020 | 31/12/2023 | James Canning |
Description | Determination of Absolute Neutrino Mass Using Quantum Technologies |
Amount | £1,897,333 (GBP) |
Funding ID | ST/T006439/1 |
Organisation | Science and Technologies Facilities Council (STFC) |
Sector | Public |
Country | United Kingdom |
Start | 02/2021 |
End | 01/2025 |
Description | Neutrino Mass and its New Physics Signatures in Phenomenology, Cosmology and Astrophysics |
Amount | £131,000 (GBP) |
Funding ID | NIF\R1\221737 |
Organisation | The Royal Society |
Sector | Charity/Non Profit |
Country | United Kingdom |
Start | 03/2023 |
End | 02/2025 |
Description | UCL Studentship |
Amount | £50,000 (GBP) |
Organisation | University College London |
Sector | Academic/University |
Country | United Kingdom |
Start | 10/2019 |
End | 09/2023 |
Description | Weak Measurements and Fundamental Physics |
Amount | £60,000 (GBP) |
Organisation | Franklin Fetzer Fund |
Sector | Charity/Non Profit |
Country | United States |
Start | 10/2019 |
End | 09/2023 |