'T-ray' breakthrough signals next generation of security sensors

Metamaterial guide makes T-ray scanners possible<em> - News Release</em>

Joint news release from Imperial College London and the University of Bath

Under strict embargo for
1800 hours GMT
Sunday 3 February 2008

A new generation of sensors for detecting explosives and poisons could be developed following new research into a type of radiation known as T-rays, published today (3 February) in Nature Photonics.

The research shows that these T-rays, electromagnetic waves in the far infrared part of the electromagnetic spectrum that have a wavelength 500 times longer than visible light, can be guided along the surface of a specially designed material, known as a metamaterial. Being able to control T-rays in this way is essential if this type of radiation is to be used in many real world applications.

Researchers believe one of the areas with the most potential to use T-rays is security sensing and scanning, because many of the molecules in explosives and biological agents like anthrax strongly absorb this radiation. If T-rays are tightly confined on surfaces in contact with such molecules then the detection sensitivity is greatly increased.

Simple metallic surfaces have been used to control T-ray propagation before, but these only weakly guide the radiation, which extends as a weak field many centimetres above the surface of the material, thus rendering it less effective for sensing. The new study has now shown that a metamaterial surface draws T-rays close to it, creating a very strong field less than a millimetre above the surface. This greatly enhances the absorption by molecules on the surface making highly effective sensing techniques possible.

The study was performed by a team of UK and Spanish physicists led in the UK by Dr Stefan Maier from Imperial College London's Department of Physics, and Dr Steve Andrews of the University of Bath. Dr Maier explains why their metamaterial design is so important:

"T-rays have the potential to revolutionise security screening for dangerous materials such as explosives. Until now it hasn’t been possible to exert the necessary control and guidance over pulses of this kind of radiation for it to have been usable in real world applications. We have shown with our material that it is possible to tightly guide T-rays along a metal sheet, possibly even around corners, increasing their suitability for a wide range of situations."

A metamaterial is a man-made material with designed electromagnetic properties which are impossible for natural materials to possess. The metamaterial created for this new research consists of a metallic surface textured with a two-dimensional array of pits. The researchers chose the dimensions of the pits so that T-rays are drawn closely to them as they travel along the surface.

Dr Andrews says that although the results of their study are very promising, more work is needed to refine the technology before such surfaces can be used for sensing applications. "At the moment only a small number of the frequencies that make up a pulse of T-ray radiation are closely confined by our metamaterial. More sophisticated designs are needed in order to make sure that the whole pulse is affected by the surface structure, so that absorption features of molecules can be clearly identified."

Dr Maier and Dr Andrews designed the metamaterial together with colleagues from Universities in Madrid and Zaragoza, with financial support from the US Air Force and the Royal Society. Their breakthrough is based on previous theoretical predictions obtained by the Spanish team together with Imperial's Professor John Pendry, published in Science in 2004.

For more information please contact:

Danielle Reeves, Imperial College London Press Office,
Tel: +44 (0)20 7594 2198
Mob: +44 (0)7803 886248
Email: Danielle.reeves@imperial.ac.uk

Andrew McLaughlin
University of Bath Press Office
Tel: +44 (0)1225 386 883
Mob: +44 (0)7966 341 357
Email: a.mclaughlin@bath.ac.uk

Notes for editors:

1. 'Highly confined guiding of terahertz surface plasmon-polaritons on structured metal surfaces' Nature Photonics, Sunday 3 January 2008.

C. R. Williams (1), S. R. Andrews (1), S. A. Maier (2), A. I. Fernandez-Dominguez (3), L. Martin-Moreno (4), and F. J. Garcia-Vidal (3).

(1) Department of Physics, University of Bath, Bath BA2 7AY, UK
(2) Experimental Solid State Group, Physics Department, Imperial College, London SW7 2AZ, UK
(3) Departamento de Fisica Teorica de la Materia Condensada, Universidad Autonoma de Madrid, E-28049 Madrid, Spain
(4) Departamento de Fisica de la Materia Condensada, Facultad de Ciencias-ICMA, Universidad de Zaragoza-CSIC, E-50009 Zaragoza, Spain

2. About Imperial College London

Imperial College London - rated the world's fifth best university in the 2007 Times Higher Education Supplement University Rankings - is a science-based institution with a reputation for excellence in teaching and research that attracts 12,000 students and 6,000 staff of the highest international quality. Innovative research at the College explores the interface between science, medicine, engineering and business, delivering practical solutions that improve quality of life and the environment - underpinned by a dynamic enterprise culture.

Website: www.imperial.ac.uk

3. The University of Bath is one of the UK's leading universities, with an international reputation for quality research and teaching. In 15 subject areas the University of Bath is rated in the top ten in the country. View a full list of the University’s press releases: http://www.bath.ac.uk/news/releases/