The studentship is funded via the EPSRC Industrial Cooperative Awards in Science & Technology (CASE) scheme, via a grant awarded to DSTL. The successful applicant will normally be required to undertake regular reporting and visits to the sponsor. For more details about the Industrial CASE scheme, see https://www.epsrc.ac.uk/skills/students/coll/icase.
The studentships are of value around £110,000, which includes £25,000 towards the research project (travel, consumables, equipment etc.), tuition fees, and an annual, tax-free stipend of approximately £16,500 per year.
Exeter has a well-established and strong track record of relevant research, and prospective students can consider projects from a wide variety of fields:
Joint supervisors: Prof Alastair Hibbins, Prof Roy Sambles, Dr Simon Horsley
External supervisor: Nathan Clow
Industry partner: DSTL
It is the focus of this project to design, model, fabricate and characterise 2D metasurfaces, or the surface 3D metamaterials or composites, that demonstrate a tensorial surface impedance. When combined with appropriate antenna designs, the findings will support future civil applications like the internet of things, high frequency imaging systems for screening, scanners and tomography systems for medical diagnostics and wireless measurement and smart meter systems.
Propagation of energy along scalar impedance surfaces for the purpose of guiding and radiating electromagnetic waves has been studied for some time. Both 1-D and 2-D artificial impedance surfaces have been explored to control guided waves and leaky-wave radiation. Indeed the 'Sievenpiper-mushroom' array  is perhaps the best known metasurface, and Exeter researchers have successfully used an inhomogeneous design based on this to fabricate and experimentally test a surface-wave Luneburg lens device . Similar structured surfaces can also be employed to reduce the height of antenna systems. This is because, at their resonant frequency, the surface forbids the propagation of surface waves, and presents a magnetic-conductor boundary condition. Unlike perfect electric conductors, materials with this magnetic boundary condition do not exist in nature: it forces the tangential components of magnetic fluxes and the normal components of electric fields to be zero. In this way radiating elements can be placed very close to the surface without the detrimental effects associated with the interference created by images sources induced by a simple metal ground plane.
This project takes our understanding beyond the current state-of-the art [3-6], and is centred around an exploration of coupling antenna eignenmodes to inhomogeneous and tensorial impedance surfaces. These metasurfaces can be those of the printed-circuit-board-type, or the surface of ‘bulk’ metamaterials or magnetic composites. Initially we will work to understand the extent of the parameter space (in terms of the boundary conditions) that can be explored. The next step is then to place a simple dipole source close to these surfaces to understand how they can influence the source’s radiation characteristics. In turn, we will consider how the efficiency, functionality or directivity of more complex antenna can be improved, as well as reduction of size or thickness, and the polarisation of the radiated beam. A resulting structure that is lightweight, potentially conformal, and with compact volume, is particularly valuable to aerospace and space applications.
The challenges are numerous and difficult, but we expect great advances in fundamental understanding and device design from a competent researcher. There are a wealth of studies in the scientific literature, and the researcher will be required to undertake a substantial review to provide the sponsors with a summary of the state-of-the-art on metasurfaces, and composite materials. He or she will need to become familiar with the physics of anisotropic, layered and magnetic materials, and the fundamentals and complexities of wave optics. The project will include analytical, modelling, fabrication and experimental elements, and the student will be expected to interact closely with other researchers working in related areas.
 D. Sievenpiper et al., “High-impedance electromagnetic surfaces with a forbidden frequency band,” IEEE Trans. Microw. Theory Tech., 47 (11), 2059, 1999.
 J. A. Dockrey et al., “Thin metamaterial Luneburg lens for surface waves,” Phys. Rev. B, 87, 125137, 2013.
 B. H. Fong et al., “Scalar and Tensor Holographic Artificial Impedance Surfaces,” IEEE Trans. Antennas Propag., 58 (10), 3212, 2010.
 R. Quarfoth and D. Sievenpiper, “Artificial Tensor Impedance Surface Waveguides,” IEEE Trans. Antennas Propag., 61 (7), 3597, 2013.
 A. M. Patel et al., “Effective Surface Impedance of a Printed-Circuit Tensor Impedance Surface (PCTIS),” IEEE Trans. Microw. Theory Tech., 61 (4), 1403, 2013.
 “Tensorial metasurface antennas radiating polarized beams based on aperture field implementation,” International Journal of Microwave and Wireless Technologies, 10 (2), 161, 2018.
How to apply
Metamaterials are fabricated microstructures having properties beyond those found in nature. They are an important new class of electromagnetic and acoustic materials with applications in many technology areas: energy storage and improved efficiency, imaging, communications, sensing and the much-hyped ‘cloaking’. Since 2014, the Centre for Doctoral Training in Metamaterials (XM2) recruited over 80 PhD students. Learn more about our science and training approach: www.exeter.ac.uk/metamaterials .
Students will choose from a wide range of taught modules, and participate in academic and personal development skills-based workshops, together with creativity events and conference-style meetings. The cohort will also be expected to disseminate their results to the international community via high-impact publications and international conferences. They will spend time working with our academic and industrial partners. Full details of the programme are available here
The University of Exeter combines world class research with excellent student satisfaction. It is a member of the Russell Group of leading research-intensive universities. Formed in 1955, the University has over 20,000 students from more than 130 different countries. Its success is built on a strong partnership with its students and a clear focus on high performance. Recent breakthroughs to come out of Exeter's research include the identification and treatment of new forms of diabetes and the creation of the world's most transparent, lightweight and flexible conductor of electricity. Exeter is ranked amongst the UK’s top 10 universities in the Higher Education league tables produced by the Times and the Sunday Times. It is also ranked amongst the world’s top 200 universities in the QS and Times Higher Education rankings
Eligible applicants: UK/EU nationals only.
Applications are made to the Metamaterials programme for a PhD in Physics/Engineering. We invite candidates to specify their project(s) of interest at the time of application.
Read more at http://www.exeter.ac.uk/studying/funding/award/?id=3449#U4kgLQvH0rZjVUSM.99
During the application process you will need to upload the documents listed below. Please prepare these before starting the application process.
- Degree transcript(s) giving information about the qualification awarded, the modules taken during the study period, and the marks for each module taken.
- An academic CV;
- A cover letter outlining your research interests in general, the title of the project you are applying for;
- A Personal Statement consisting of two parts*:
- Describe a) why you would like to study for a PhD, b) why you would like to focus on this particular topic, c) any relevant expertise and d) your future career ambitions;
- Describe the qualities that you believe will make you a great researcher (in particular as part of a team).
You will be asked to provide the contact details of two academic referees.
* We foster creativity and utilisation of individual strengths. Applicants are encouraged to provide evidence to support their statements. This might include conventional written documents (e.g. examples of work), but we also encourage alternatives such as audio or video recordings, websites, programming etc. Please ensure to include accessible links to such files in an appropriately named document as part of the upload process.
Applications will normally be reviewed within two weeks of receipt.
Candidates will be short-listed against a set of agreed criteria to ensure quality while maintaining diversity. Failure to include all the elements listed above may result in rejection.
The essential criteria:
- Undergraduate degree in a relevant discipline (minimum 2:1);
- Vision and motivation (for research & professional development);
- Evidence of the ability to work collaboratively and to engage in a diverse community;
- Evidence of excellent written and oral skills in English.
The highest quality candidates will also be able to demonstrate one of more of the following:
- Specialist knowledge about one or more of the 8 research areas listed above;
- Training in research methodology (e.g. undergraduate research projects);
- Research outputs (e.g. papers) and/or other indicators of academic excellence (e.g. awards).
Shortlisted candidates will be invited to an entry interview to assess fit to the CDT concept. This will be held prior the academic interview with the supervisors and will normally be undertaken by a panel of 3 people, including a current postgraduate researcher or post-doc in Physics or Engineering.
Interviews are expected to start within two weeks upon application receipt. It is therefore advisable to apply as soon as possible.
Please email email@example.com if you have any queries about this process.
31st March 2020
Number of awards:
The studentship is of value around £110,000, which includes £25,000 towards the research project (travel, consumables, equipment etc.), tuition fees, and an annual, tax-free stipend of approximately £16,500 per year.
Duration of award:
Contact: Dr. Isaac Luxmoore (Admissions Tutor) firstname.lastname@example.org