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Details of Grant 

EPSRC Reference: EP/I004173/1
Title: Metal-glass nanocomposites through nanoengineering to application.
Principal Investigator: ABDOLVAND, Professor A
Other Investigators:
Researcher Co-Investigators:
Project Partners:
Department: Physics
Organisation: University of Dundee
Scheme: Career Acceleration Fellowship
Starts: 01 August 2010 Ends: 31 July 2015 Value (£): 1,066,449
EPSRC Research Topic Classifications:
Lasers & Optics Materials Processing
Optical Devices & Subsystems
EPSRC Industrial Sector Classifications:
No relevance to Underpinning Sectors
Related Grants:
Panel History:
Panel DatePanel NameOutcome
09 Jun 2010 EPSRC Fellowships 2010 Interview Panel A Announced
Summary on Grant Application Form
For many centuries the presence of metal nanoparticles has been evident because of the unusual colour effects associated with them. The red and yellow colours of many medieval church windows originated from silver, gold and copper nanoparticles embedded in the window glass. The first evidence of using gold nanoparticles in antiquity dates back to the 4th century AD (The Lycurgus Cup). The physics of the processes remained a mystery until Michael Faraday, the well-known 19th century physicist, discovered that this effect is due to a new type of optical absorption in metal particles with dimensions substantially less than the wavelength of light. Metal particles which have sizes of the order of one to several hundreds of nanometres, are the subject of intensive research efforts across the world. This is due to the fascinating differences in the optical properties they exhibit compared to bulk metals. When a metal nanoparticle is smaller than the wavelength of light, the light reflected from it is replaced by light scattering, which is particularly strong at the resonance frequencies of collective electron excitations in the nanoparticle. These oscillations are known as particle plasmons or surface plasmon resonances. For noble and alkali metals, where the conduction electrons are sufficiently free-electron-like, the collective excitations show themselves as pronounced resonance effects in optical scattering and absorption spectra. Recent advances in nanotechnology have made it possible to create artificial nanostructured composite materials whose optical properties are determined by their structure, rather than by the characteristics of their constituents. These optical properties are distinctly different from those of conventional composites. Such nanocomposites are often referred to as metamaterials. The most established way to manufacture metamaterials for photonics applications is by engineering the optical response of large groups of repeated submicron patterns, lithographically formed from metal films, using rigorous grating theory for the description of the optical properties of a given pattern. Here, I propose the development of metamaterials that - in the spirit of the original meaning of this term - are based on nanostructured composite materials and exhibit exceptional properties due to the inclusion of artificially implanted inhomogeneities. This concept is based on tailoring the properties of, and providing new functionalities to, artificial materials created by controllable formation of metal nanoparticles in glass matrices; so-called metal-glass nanocomposites (MGNs).I will systematically investigate the entire range of parameters necessary to develop metamaterials by exploiting the generic functionalities of patterned MGNs. These artificial nanomaterials will be designed and investigated in detail utilising a combination of a novel fabrication techniques, and by modifying/tailoring their optical properties with short and ultra-short laser pulses. The technology developed will find a wide range of applications not only in optics and optical industries via optical amplifying, switching and polarisation control, but also in micro- and optoelectronics - e.g. the integration of optical and electronic components at extremely small scales for optical computing. Given the broad application potential for these materials it would be possible to optimise the outcomes and generate internationally competitive output in several key areas of science and technology. A number of manufacturers and industries will ultimately benefit from the work - e.g. computer chip industries, manufacturers of optical data storage devices for security applications, optical sensing devices, display technology, healthcare devices and artists/manufacturers of contemporary jewellery. I believe that the proposed programme will address key problems in this field and will contribute to the UK's leading position in this area of research.
Key Findings
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Potential use in non-academic contexts
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Project URL: http://mapsatepm.org.uk/people/dr-amin-abdolvand-2/
Further Information:  
Organisation Website: http://www.dundee.ac.uk