Beam driven instabilities in magnetized plasmas
Lead Research Organisation:
University of Strathclyde
Department Name: Physics
Abstract
Electromagnetic radiation is another, broader, name for light, encompassing radio waves through to gamma rays. This proposal intends to investigate the ability of an electron beam gyrating in a fixed magnetic field to interact with an electromagnetic wave, in the microwave part of the spectrum. In certain conditions this interaction can be arranged so that the electrons slow down, and the energy they lose is conserved by an increase in the energy of the wave. This process is effectively LASER action. In particular the project will consider an electron beam where some electrons are very nearly travelling along the magnetic field lines and others are gyrating nearly perpendicularly to it. A new theoretical idea has been proposed as a result of astronomical observations which expects especially high growth rates to occur from this type of electron beam and potentially efficient conversion of the electron energy to wave energy. To evaluate this potential, and the validity of the theoretical idea, the project will conduct an experiment where such a beam will be produced by magnetic compression and the emissions from the beam will be observed for different values of the magnetic field and radiation field distributions. Measurements of the beam current, voltage position and velocity will be compared to the measurements of the amplitude and frequency of the microwave emissions. Theoretical research will also be undertaken to ensure the expected behaviour is compared accurately with the actually realisable experimental geometry. This combined approach of theoretical and experimental investigation will allow the project to compare the experimental results with the predictions of the theoretical model and also with the output of computational simulations, thereby establishing its validity and potential for applications.
Publications
BINGHAM R
(2010)
Lower-hybrid waves generated by anomalous Doppler resonance in auroral plasmas
in Journal of Plasma Physics
Bingham R
(2013)
Laboratory astrophysics: Investigation of planetary and astrophysical maser emission
in Space Science Reviews
Bowes D
(2014)
X-ray emission as a diagnostic from pseudospark-sourced electron beams
in Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms
Bowes D
(2014)
Visualization of a Pseudospark-Sourced Electron Beam
in IEEE Transactions on Plasma Science
Cairns R
(2011)
Cyclotron maser radiation from inhomogeneous plasmas
in Physics of Plasmas
Cairns RA
(2008)
Cyclotron maser radiation from an inhomogeneous plasma.
in Physical review letters
Cross A
(2019)
Oversized W-band 2D Periodic Lattice Oscillator
Donaldson C
(2019)
0.37 THz gyro-TWA with a cryo-free SCM: Design and simulation
Gargaté L
(2010)
THE NONLINEAR SATURATION OF THE NON-RESONANT KINETICALLY DRIVEN STREAMING INSTABILITY
in The Astrophysical Journal
Gillespie K
(2008)
3D PiC code simulations for a laboratory experimental investigation of Auroral Kilometric Radiation mechanisms
in Plasma Physics and Controlled Fusion
| Description | Theory, numerical modelling and laboratory experiments were used to understand the physical mechanism of certain types of electron beam driven instabilities in magnetized plasmas. It was established that the horseshoe instability is responsible for electromagnetic emissions observed when an electron beam is injected along a converging magnetic field in the presence of a tenuous plasma. |
| Exploitation Route | Applications of this research to detailed understanding of plasma instabilities both in the laboratory and in magnetospheres. |
| Sectors | Energy,Environment,Other |
| Description | The impact this would have is twofold. First, there is the obvious benefit to the environment, but second, the development and ultimate commercialisation of such technology would create wealth for the UK's economy. The current extraction process used by the mining industry involves passing rocks through a crusher to reduce them to a fine dust from which minerals and ore can be removed. However, this simple process comes at a high cost and uses an estimated 4% of the world's energy resources. This is where high-power magnetrons could make a big difference. When you put something unsuitable in your microwave, like a china cup, it tends to crack. If you do the same with rock, it also cracks, so that when you come to crush it, it just crumbles. High-power magnetrons would be used to pre-treat rocks with microwaves in order to reduce the amount of energy required to crush them. Funding provided by the EPSRC, under its Pathways to Impact programme, will help Adrian Cross and his team to reach their goal. The award will be used to initialise a collaboration with e2v Technologies, a UK-based company already manufacturing and selling world-class magnetron technology. "e2v is one of the companies in the UK that can exploit the technology that we are developing," explains Cross. "We want to provide impact by working with e2v, who have the market to sell these high-power magnetrons worldwide." Two members of the Strathclyde group are already working in tandem with e2v, thanks to the EPSRC's funding. The hope is that the collaboration will pool together the design expertise of the Cross group with the manufacturing capabilities of e2v to produce a truly world-leading high-power magnetron. . |
| First Year Of Impact | 2009 |
| Sector | Energy,Environment,Other |
| Impact Types | Cultural |
| Description | Joint research with University of St Andrews |
| Organisation | University of St Andrews |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | University of Strathclyde researchers worked on this project with researchers from University of St Andrews |
| Collaborator Contribution | Dr. I. Vorgul of the University of St Andrews contributed her theoretical and computational expertise to the interpretation of the research results from this project. |
| Impact | Joint publications in international refereed research journals with Dr. I. Vorgul as a co-author. |
| Start Year | 2006 |
| Description | Research collaboration with Prof. Mark Koepke, University of West Virginia, USA |
| Organisation | West Virginia University |
| Country | United States |
| Sector | Academic/University |
| PI Contribution | Host : Hosting academic visitor : Research collaborations during visits of Prof. Mark Koepke, University of West Virginia, USA to University of Strathclyde |
| Collaborator Contribution | Prof. Mark Koepke contributed his extensive expertise in plasma physics, especially in the interpretation of plasma probe analysis. |
| Impact | Joint publications in international refereed journals with Prof Mark Koepke as a co-author. |
| Start Year | 2007 |
| Description | Research collaboration with Prof. R. Alan Cairns, University of St Andrews |
| Organisation | University of St Andrews |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Host : Hosting academic visitor : Collaboration in plasma physics research with Prof. R. Alan Cairns of the University of St. Andrews |
| Collaborator Contribution | Prof. R. Alan Cairns contributed his extensive experience and theoretical expertise in plasma physics to the understanding of the results of this project. Prof. Cairns has been appointed as a Visiting Professor to Strathclyde University. |
| Impact | Many significant joint research publications in international refereed research journals with Prof. R. Alan Cairns as a co-author have resulted from this collaboration. |
| Start Year | 2006 |
| Description | Invited Seminar at Glasgow University |
| Form Of Engagement Activity | Scientific meeting (conference/symposium etc.) |
| Part Of Official Scheme? | No |
| Type Of Presentation | keynote/invited speaker |
| Geographic Reach | Regional |
| Primary Audience | Public/other audiences |
| Results and Impact | Visitor : Invited talk : Invited Seminar at Glasgow University . Several enquiries from students interested in entering plasma physics as a research career. |
| Year(s) Of Engagement Activity | 2010 |
| Description | Research collaboration with Prof. Mark Koepke, University of West Virginia, USA |
| Form Of Engagement Activity | A formal working group, expert panel or dialogue |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Professional Practitioners |
| Results and Impact | Host : Hosting academic visitor : Research collaborations during visits of Prof. Mark Koepke, University of West Virginia, USA to University of Strathclyde . Several joint research papers were published by our group in international refereed research journals with Prof. Mark Koepke as a co-author. |
| Year(s) Of Engagement Activity | 2008 |
| Description | Research collaboration with Prof. R. Alan Cairns, University of St Andrews |
| Form Of Engagement Activity | Scientific meeting (conference/symposium etc.) |
| Part Of Official Scheme? | No |
| Type Of Presentation | paper presentation |
| Geographic Reach | Local |
| Primary Audience | Professional Practitioners |
| Results and Impact | Host : Hosting academic visitor : Collaboration in plasma physics research with Prof. R. Alan Cairns of the University of St. Andrews . Prof. R. Alan Cairns has been appointed as a Visiting Professor to our research group at the University of Strathclyde. |
| Year(s) Of Engagement Activity | Pre-2006,2006,2007,2008,2009,2010,2011,2012,2013,2014 |