Systematically characterising the exotic material properties of weakly collisional plasmas
Lead Research Organisation:
University of Oxford
Department Name: Oxford Physics
Abstract
Many of the most challenging conundrums currently being addressed by frontier scientific research in astrophysics involve interactions between exotic objects of colossal sizes and/or energies, typically resulting in instances of extraordinary energy release:
- the electromagnetic fireworks accompanying black-hole mergers, which are now observable with the advent of gravitational- wave and multi-messenger astronomy;
- galaxy formation in clusters;
- accretion discs and jets, which are now serially observable by the Event Horizon radio-telescope network;
- gamma-ray and fast radio bursts; ultra-high-energy cosmic rays; and many other occurrences.
To model these phenomena, a key challenge is to have a detailed understanding of the dilute hot gas (known as `plasma') making up the astrophysical environments where these events occur.
Unsurprisingly, this plasma is believed to behave very differently to the gases we all encounter in everyday life, on account of being millions of degrees hotter, and one sextillionth the density! While this state of matter has been studied by physicists for nearly a century - most famously, in the contexts of stars and nuclear fusion energy research - there remain a number of surprisingly fundamental uncertainties about its properties: for example, how do plasmas conduct heat, and what is their viscosity? However, recent technological advances in both our computing capabilities and high-energy laser facilities mean that we can now investigate the behaviour of plasmas as never before in the laboratory and on supercomputers.
In this research project, I will be undertaking a systematic programme that will significantly advance our understanding of the fundamental properties of the type of plasma typically encountered in astrophysical environments (whose thermal energy exceeds their magnetic energy). More specifically, I will run numerical simulations with state-of-the-art codes to investigate several different characteristics: viscosity, thermal and electrical conductivity, and the spontaneous generation of charged particles with anomalously high energies. I am particularly interested in behaviours which depart markedly from conventional gases. I will then test theoretical frameworks developed in "laboratory astrophysics" experiments, which use lasers to realise extreme conditions on Earth with many similarities to relevant astrophysical environments.
In addition to the astrophysical observations, I am also interested in leveraging anomalous properties of magnetised plasmas to aid inertial confinement fusion (ICF) efforts. In ICF schemes, a small capsule of deuterium-tritium fuel is ignited using laser beams; if the scheme is successful, the resulting nuclear fusion reactions produce much more energy than initially applied with the lasers. At present, successful ICF schemes have not yet been achieved; however, I believe that significant improvements to current attempts could be attained by considered use of applied magnetic fields.
- the electromagnetic fireworks accompanying black-hole mergers, which are now observable with the advent of gravitational- wave and multi-messenger astronomy;
- galaxy formation in clusters;
- accretion discs and jets, which are now serially observable by the Event Horizon radio-telescope network;
- gamma-ray and fast radio bursts; ultra-high-energy cosmic rays; and many other occurrences.
To model these phenomena, a key challenge is to have a detailed understanding of the dilute hot gas (known as `plasma') making up the astrophysical environments where these events occur.
Unsurprisingly, this plasma is believed to behave very differently to the gases we all encounter in everyday life, on account of being millions of degrees hotter, and one sextillionth the density! While this state of matter has been studied by physicists for nearly a century - most famously, in the contexts of stars and nuclear fusion energy research - there remain a number of surprisingly fundamental uncertainties about its properties: for example, how do plasmas conduct heat, and what is their viscosity? However, recent technological advances in both our computing capabilities and high-energy laser facilities mean that we can now investigate the behaviour of plasmas as never before in the laboratory and on supercomputers.
In this research project, I will be undertaking a systematic programme that will significantly advance our understanding of the fundamental properties of the type of plasma typically encountered in astrophysical environments (whose thermal energy exceeds their magnetic energy). More specifically, I will run numerical simulations with state-of-the-art codes to investigate several different characteristics: viscosity, thermal and electrical conductivity, and the spontaneous generation of charged particles with anomalously high energies. I am particularly interested in behaviours which depart markedly from conventional gases. I will then test theoretical frameworks developed in "laboratory astrophysics" experiments, which use lasers to realise extreme conditions on Earth with many similarities to relevant astrophysical environments.
In addition to the astrophysical observations, I am also interested in leveraging anomalous properties of magnetised plasmas to aid inertial confinement fusion (ICF) efforts. In ICF schemes, a small capsule of deuterium-tritium fuel is ignited using laser beams; if the scheme is successful, the resulting nuclear fusion reactions produce much more energy than initially applied with the lasers. At present, successful ICF schemes have not yet been achieved; however, I believe that significant improvements to current attempts could be attained by considered use of applied magnetic fields.
Publications
Davies J
(2023)
Quantitative proton radiography and shadowgraphy for arbitrary intensities
in High Energy Density Physics
Schaeffer D
(2023)
Proton imaging of high-energy-density laboratory plasmas
in Reviews of Modern Physics
| Description | Although this award is still active, and in its earlier stages, it has enabled me to take a significant step towards understanding the material properties of magnetised weakly collisional plasmas - the state of matter that is the primary focus of this award - by predicting the conditions under which classical models for these properties should succeed or fail. I have found that, generically, if the magnetic fields are either very strong or weak, the classical models should work, but that for magnetic fields of intermediate strength, they should not. These results are consistent with previous experimental results. I plan to determine revised models in this latter case during the rest of the award using a new simulation technique that we are currently developing, as well as carrying out new laser-plasma experiments to test these models and predictions. I have also done some work developing the analysis of proton images, a key diagnostic technique in laser-plasma experiments for measuring electromagnetic fields that I will be using on the experiments I will be undertaking during my FLF. |
| Exploitation Route | Our findings so far should be of use to all researchers who study weakly collisional plasma environments in identifying when the classical material properties models that are typically adopted when simulating these plasmas can be relied. In addition to other academic research fields, this also impacts research in the Energy sector (fusion energy) and other industrial plasma modellers. Going forwards, it is our intention that any new models that we derive would be available to researchers in all of these areas. |
| Sectors | Aerospace Defence and Marine Energy |
| Description | Although this grant is still in its earlier stages, some of our initial results are beginning to have non-academic impacts. More specifically, presenting the results of our initial theoretical studies, which are due to be published in a peer-reviewed journal shortly, to one of my institutions' industrial partners in March 2023 has helped to prompt them to support new research on magnetised plasma microphysics, in order to meet their long-term goal of high-fidelity modelling of plasmas. It is our plan to continue to widen this impact to both publicly funded national laboratories and private fusion companies my institution partners within the Energy sector. |
| First Year Of Impact | 2023 |
| Sector | Aerospace, Defence and Marine |
| Impact Types | Societal Economic |
| Description | Invited speaker at STFC UK XFEL workshop |
| Geographic Reach | National |
| Policy Influence Type | Contribution to a national consultation/review |
| URL | https://xfel.ac.uk/ |
| Description | Invited speaker to APOLLON workshop in Paris |
| Geographic Reach | National |
| Policy Influence Type | Contribution to a national consultation/review |
| URL | https://apollonlaserfacility.cnrs.fr/en/home/ |
| Description | Published first review of proton imaging in high-energy density plasmas |
| Geographic Reach | Multiple continents/international |
| Policy Influence Type | Influenced training of practitioners or researchers |
| Impact | By completing the review, we have laid down in writing the first clear description of how proton imaging is best implemented, and data should be analysed, and also identified key areas in which new research is needed. It is our intention to have helped to improve research that uses this diagnostic, and also establish future research agendas. |
| Description | PhD: Understanding the anomalous material properties of weakly collisional plasmas |
| Amount | £124,852 (GBP) |
| Organisation | Atomic Weapons Establishment |
| Sector | Private |
| Country | United Kingdom |
| Start | 09/2023 |
| End | 03/2027 |
| Description | Graduate Open Days for Astrophysics at the University of Oxford |
| Form Of Engagement Activity | Participation in an open day or visit at my research institution |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Undergraduate students |
| Results and Impact | The event, which is held every year in the Astrophysics subdepartment in Oxford Physics, is an opportunity for prospective DPhil students to come to hear about the research carried out in Astrophysics and ask prospective supervisors questions about specific projects. For the last two years, I have presented a poster about my FLF programme and associated studentship opportunities. |
| Year(s) Of Engagement Activity | 2022,2023 |
| Description | Graduate Open Days for Atomic and Laser Physics at the University of Oxford |
| Form Of Engagement Activity | Participation in an open day or visit at my research institution |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Undergraduate students |
| Results and Impact | The event, which is held every year in the Atomic and Laser Physics (ALP) subdepartment in Oxford Physics, is an opportunity for prospective DPhil students to come to hear about the research carried out in ALP, see the laboratories in the subdepartment, and ask prospective supervisors questions about specific projects. For the last two years, I have given a 10 minute talk about my FLF programme, and linked it to possible studentships. |
| Year(s) Of Engagement Activity | 2022,2023 |
| Description | Speaker at 'Saturday Mornings in Theoretical Physics' event |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Other audiences |
| Results and Impact | The 'Saturday Mornings of Theoretical Physics Talks', which are hosted by Rudolf Peierls Centre for Theoretical Physics at the University of Oxford and are open to all Oxford alumni and current students, centre around three 45 minute talks given by leading theoretical physicists that explain an area of research to an audience familiar with physics at about the second-year undergraduate level. I gave one of these talks at an event in May 2023 on inertial confinement fusion, talking about its history and the physics underlying it, as well as the applications of my research to this energy-generation concept. The talk was recorded, and was subsequently turned into a podcast listened to internationally. |
| Year(s) Of Engagement Activity | 2023 |
| Description | Speaker at `Out Thinkers' event |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Postgraduate students |
| Results and Impact | Out Thinkers is a seminar series run by the charity Pride in STEM at which LGBT+ speakers from different parts of physics give short talks about their research. This particular event is held in February every year in the Department of Physics in Oxford to celebrate LGBT+ history month. In 2023, I was one of the speakers, talking about my FLF research. |
| Year(s) Of Engagement Activity | 2023 |