Piecing together the Neutrino Mass Puzzle in Search of New Particles with Precision Oscillation Experiments and Quantum Technologies
Lead Research Organisation:
University College London
Department Name: Physics and Astronomy
Abstract
Neutrino physics has the potential to revolutionise our current understanding of the universe.
The elusive neutrino is the most abundant massive particle in nature, but one of the most tricky to measure, because of its interaction properties. One hundred trillion neutrinos from the sun are passing through your body every second, but the chance of them actually stopping is incredibly small; if you lived to be one quadrillion years old, it's possible one may stop inside during your lifetime. Over the past five decades, neutrino experiments have overcome this challenge by developing new detector and particle beam technologies, however, in this relatively modern field, many properties and interactions of the neutrino remain shrouded in mystery.
One puzzle is the ever-increasing number of hints that there may be more neutrinos than the three we have already discovered. Does a fourth "sterile" neutrino, exist? Could it be Dark Matter? My passion is to develop novel technology which allows me to make more precise measurements than ever before of neutrinos, to answer these questions.
As a research fellow, I will use the first data from the Short Baseline Neutrino (SBN) programme: an innovative system of detectors that I spent the past seven years building, to investigate a phenomenon called neutrino oscillations. Measuring this process gives us an opportunity to probe the existence of new kinds of neutrino. Using these state-of-the-art neutrino detectors, called liquid argon Time Projection Chambers, I will measure neutrino interactions, and lead a search for sterile neutrinos with SBN.
More clues can be found in a complementary search: measuring the mass of neutrinos. In the radioactive decay of tritium, an electron and a neutrino are emitted. Using what we know about the masses of the three known neutrinos, I will use energy conservation to look for evidence of a fourth.
Directly measuring the neutrino mass is extremely challenging. Even though the neutrino is the most abundant massive particle in the universe, we can't precisely say what its mass is. My goal is to combine quantum measurement techniques with an emerging technology called Cyclotron Radiation Emission Spectroscopy, to create a detector which can measure the neutrino mass with unprecedented precision. Current detector technologies are unable to directly measure the absolute mass of the neutrino, but this project will lay groundwork for the ultimate future experiment: solving the neutrino mass puzzle by direct measurement.
The elusive neutrino is the most abundant massive particle in nature, but one of the most tricky to measure, because of its interaction properties. One hundred trillion neutrinos from the sun are passing through your body every second, but the chance of them actually stopping is incredibly small; if you lived to be one quadrillion years old, it's possible one may stop inside during your lifetime. Over the past five decades, neutrino experiments have overcome this challenge by developing new detector and particle beam technologies, however, in this relatively modern field, many properties and interactions of the neutrino remain shrouded in mystery.
One puzzle is the ever-increasing number of hints that there may be more neutrinos than the three we have already discovered. Does a fourth "sterile" neutrino, exist? Could it be Dark Matter? My passion is to develop novel technology which allows me to make more precise measurements than ever before of neutrinos, to answer these questions.
As a research fellow, I will use the first data from the Short Baseline Neutrino (SBN) programme: an innovative system of detectors that I spent the past seven years building, to investigate a phenomenon called neutrino oscillations. Measuring this process gives us an opportunity to probe the existence of new kinds of neutrino. Using these state-of-the-art neutrino detectors, called liquid argon Time Projection Chambers, I will measure neutrino interactions, and lead a search for sterile neutrinos with SBN.
More clues can be found in a complementary search: measuring the mass of neutrinos. In the radioactive decay of tritium, an electron and a neutrino are emitted. Using what we know about the masses of the three known neutrinos, I will use energy conservation to look for evidence of a fourth.
Directly measuring the neutrino mass is extremely challenging. Even though the neutrino is the most abundant massive particle in the universe, we can't precisely say what its mass is. My goal is to combine quantum measurement techniques with an emerging technology called Cyclotron Radiation Emission Spectroscopy, to create a detector which can measure the neutrino mass with unprecedented precision. Current detector technologies are unable to directly measure the absolute mass of the neutrino, but this project will lay groundwork for the ultimate future experiment: solving the neutrino mass puzzle by direct measurement.
Organisations
- University College London (Lead Research Organisation)
- UNIVERSITY OF OXFORD (Collaboration)
- University College London (Collaboration)
- National Physical Laboratory (Collaboration)
- Fermilab - Fermi National Accelerator Laboratory (Collaboration)
- University of Warwick (Collaboration)
- SWANSEA UNIVERSITY (Collaboration)
- UNIVERSITY OF CAMBRIDGE (Collaboration)
- Queen Mary University of London (Fellow)
Publications
Abed Abud A
(2023)
Impact of cross-section uncertainties on supernova neutrino spectral parameter fitting in the Deep Underground Neutrino Experiment
in Physical Review D
Abed Abud A
(2022)
Separation of track- and shower-like energy deposits in ProtoDUNE-SP using a convolutional neural network
in The European Physical Journal C
Abed Abud A
(2023)
Highly-parallelized simulation of a pixelated LArTPC on a GPU
in Journal of Instrumentation
Abratenko P
(2022)
Search for an Excess of Electron Neutrino Interactions in MicroBooNE Using Multiple Final-State Topologies.
in Physical review letters
Abratenko P
(2022)
Search for an anomalous excess of charged-current quasielastic ? e interactions with the MicroBooNE experiment using Deep-Learning-based reconstruction
in Physical Review D
Abratenko P
(2022)
Search for an anomalous excess of charged-current ? e interactions without pions in the final state with the MicroBooNE experiment
in Physical Review D
Abratenko P
(2024)
Measurement of ambient radon progeny decay rates and energy spectra in liquid argon using the MicroBooNE detector
in Physical Review D
Abratenko P
(2022)
Search for long-lived heavy neutral leptons and Higgs portal scalars decaying in the MicroBooNE detector
in Physical Review D
Abratenko P
(2023)
First Constraints on Light Sterile Neutrino Oscillations from Combined Appearance and Disappearance Searches with the MicroBooNE Detector.
in Physical review letters
Abratenko P
(2024)
Search for Heavy Neutral Leptons in Electron-Positron and Neutral-Pion Final States with the MicroBooNE Detector.
in Physical review letters
| Description | URA visiting scholars programme |
| Amount | $12,644 (USD) |
| Funding ID | 186357 |
| Organisation | The Universities Research Association |
| Sector | Academic/University |
| Country | United States |
| Start | 04/2023 |
| End | 08/2024 |
| Title | MicroBooNE dataset |
| Description | The MicroBooNE experiment took data between 2015-2021, recording 500,000 neutrino interactions. The final parts of this experimental data is still under processing and analysis. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2016 |
| Provided To Others? | No |
| Impact | MicroBooNE analysis and publications are still ongoing, (see all MicroBooNE publications outcomes). The full processed datasets will be released in an appropriate way for use in the wider research community with the release of the final publications. |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | National Physical Laboratory |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | Swansea University |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | University College London |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | University of Cambridge |
| Department | Department of Physics |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | University of Oxford |
| Department | Department of Physics |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Quantum Technologies for Neutrino Mass (QTNM) |
| Organisation | University of Warwick |
| Department | Department of Physics |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | I joined the QTNM project in 2022 as an Ernest Rutherford Fellow, and leads the CRESDA system integration taskforce, and coordinate the Conceptual Design Report; an important deliverable for the first phase of the QTNM project. I also leads simulation work for the detector calibration taskforce, and am an editor of the forthcoming first full-collaboration publication, QTNM White Paper. I lead the QTNM collaboration's outreach and dissemination team. In 2023 I created a team of summer interns (funded by UCL) to create a website and a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024. |
| Collaborator Contribution | The QTFP funded Quantum Technologies for Neutrino Mass project brings together technology and expertise in atomic physics, quantum technology, high frequency signal collection and processing. The collaborating institutions bring expertise in these areas forming a collaboration with particle physicists. Financially UCL provided the funding for the two interns, via a MAPS studentship and Brian Duff Scholarship scheme. |
| Impact | This multidisciplinary project has resulted in developments in atomic physics, quantum technology and high frequency signal collection, however these are small author-list publications which are not listed under outcomes for this project. |
| Start Year | 2022 |
| Description | Short-Baseline Neutrino (SBN) Programme |
| Organisation | Fermilab - Fermi National Accelerator Laboratory |
| Department | MicroBooNE Experiment |
| Country | United States |
| Sector | Public |
| PI Contribution | Short Baseline Near Detector (SBND) and MicroBooNE both form part of the three-detector SBN programme. McConkey is one of the driving forces behind realising SBND. She has been involved in this project since the design phase, taking significant leadership roles in the realisation of the detector over the course of her involvement, most recently as Installation and Assembly Coordinator. Her leadership supported the UK-funded TPC components through construction, assembly, and installation, enabling the rich physics programme that lies in SBND's near future. McConkey currently co-leads the TPC commissioning team, developing tools to test and optimise the detector operation. McConkey published world leading measurements with MicroBooNE, of electron neutrino cross-section on argon, and the world's first differential electron neutrino-Ar cross-section in lepton energy, and is currently working on a measurement of the exclusive anti-electron neutrino cross-section on argon. McConkey leads a major detector decommissioning investigation on MicroBooNE studying the decline of the light-yield in the detector over time. |
| Collaborator Contribution | Fermilab is the host laboratory for both SBND and MicroBooNE providing the corresponding technical resources to assemble, install and operate both detectors. Both collaborations have global involvement, and many major components of SBND were designed and assembled in the UK, funded by STFC. Subsequent travel support has enabled continued involvement in this project. The University Reasearch Association (URA) funded the travel for a postdoc in McConkey's research team to spend an extended period at Fermilab for detector commissioning. |
| Impact | All papers listed are outcomes from this collaboration. |
| Start Year | 2014 |
| Description | Short-Baseline Neutrino (SBN) Programme |
| Organisation | Fermilab - Fermi National Accelerator Laboratory |
| Country | United States |
| Sector | Public |
| PI Contribution | Short Baseline Near Detector (SBND) and MicroBooNE both form part of the three-detector SBN programme. McConkey is one of the driving forces behind realising SBND. She has been involved in this project since the design phase, taking significant leadership roles in the realisation of the detector over the course of her involvement, most recently as Installation and Assembly Coordinator. Her leadership supported the UK-funded TPC components through construction, assembly, and installation, enabling the rich physics programme that lies in SBND's near future. McConkey currently co-leads the TPC commissioning team, developing tools to test and optimise the detector operation. McConkey published world leading measurements with MicroBooNE, of electron neutrino cross-section on argon, and the world's first differential electron neutrino-Ar cross-section in lepton energy, and is currently working on a measurement of the exclusive anti-electron neutrino cross-section on argon. McConkey leads a major detector decommissioning investigation on MicroBooNE studying the decline of the light-yield in the detector over time. |
| Collaborator Contribution | Fermilab is the host laboratory for both SBND and MicroBooNE providing the corresponding technical resources to assemble, install and operate both detectors. Both collaborations have global involvement, and many major components of SBND were designed and assembled in the UK, funded by STFC. Subsequent travel support has enabled continued involvement in this project. The University Reasearch Association (URA) funded the travel for a postdoc in McConkey's research team to spend an extended period at Fermilab for detector commissioning. |
| Impact | All papers listed are outcomes from this collaboration. |
| Start Year | 2014 |
| Title | Short-Baseline Near Detector |
| Description | Short-Baseline Near Detector (SBND) is a liquid argon time projection chamber (LArTPC) detector which will measure neutrino interactions. |
| Type Of Technology | New/Improved Technique/Technology |
| Year Produced | 2024 |
| Impact | SBND will measure and unprecedentedly large number of neutrino interactions, which has the potential to change our understanding of particle physics and the standard model. These results (which will lead from the next 3 years of data taking) are an important input to the next generation of neutrino experiments. |
| URL | https://sbn-nd.fnal.gov/collaboration.html |
| Description | Neutrinos from Home talk |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Other audiences |
| Results and Impact | As an invited speaked for the "Neutrinos from Home" online conference, I created a Pegogogical talk about Neutrino Mass Measurement experiments. The goal of the conference is to bridge the gaps in understanding between the fields of Experimental Particle Physics, Astronomy and Theory. The pedagogical talk was aimed at bringing the non-particle physicists up to speed with current state of the art in experimental particle physics. There was a dedicated discussion session with engaged participants and many interesting questions. |
| Year(s) Of Engagement Activity | 2024 |
| URL | https://neutrinos.cosmodiscussion.com |
| Description | QTNM Outreach projects -- website and schools resource pack |
| Form Of Engagement Activity | Engagement focused website, blog or social media channel |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Schools |
| Results and Impact | Created a website for Quantum Technologies for Neutrino Mass project, suitable for both scientific and general audiences. Created a Quantum Technology resource pack for 11-13 year olds which will be piloted in schools in 2024 |
| Year(s) Of Engagement Activity | 2023,2024 |
| Description | SBND Calibration and Commissioning Workshop |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Postgraduate students |
| Results and Impact | This research-focussed workshop enabled two working groups within the Short-Baseline Near Detector collaboration to exchange information and tools. The goal was to kickstart the UK postgraduate students' involvement in the ongoing efforts. The workshop resulted in improved communication between the two working groups, and gave the new students both contacts, and relevant tasks to move forward with following the workshop. |
| Year(s) Of Engagement Activity | 2024 |
| Description | SNOLab invited talk on QTNM |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Study participants or study members |
| Results and Impact | 50 scientists attended a workshop on the use of quantum technology in particle physics experiments. The goal was to bring together experts from different scientific communities to identify challenges and plan for future quantum-enabled particle detection experiments. This workshop built interdisciplinary understanding, and led to potential future collaboration. |
| Year(s) Of Engagement Activity | 2024 |
| URL | https://indico.cern.ch/event/1345184/ |