Nanocoatings

The number of material systems that can be used for nanolayer coatings is vktuaHy unHmited. Any refractory hard material can be used as the hard material compatible metal can be used as the tough material. Examples of material systems for nanocoatings include the foUowing ... 

Carmichael D, Mathey F (2002) New Trends in Phosphametallocene Chemistry. 220 27-51 Caruso F (2003) Hollow Inorganic Capsules via Colloid-Templated Layer-by-Layer Electrostatic Assembly. 227 145-168 Caruso RA (2003) Nanocasting and Nanocoating. 226 91-118 Ceroni P, see Balzani V (2003) 228 159-191 Chamberlin AR, see Gilmore MA (1999) 202 77-99 Chasseau D, see Guionneau P (2004) 234 97-128... 

Del Villar, I. Corres, J. M. Achaerandio, M. Arregui, F. J. Mafias, I. R., Spectral evolu tion with incremental nanocoating of long period fiber gratings, Opt. Express 2006, 14, 11972 11981... 

Pilla, P. Giordano, M. Korwin Pawlowski, M. L. Bock, W. J. Cusano, A., Sensitivity characteristics tuning in tapered long period gratings by nanocoatings, IEEE Photon. Technol. Lett. 2007, 19, 1517 1519... 

Kurokawa H, Sholkalapper TZ, Jacobson CP, De Johghe LC, and Visco SJ. Ceria nanocoating for sulfur tolerant Ni-based anodes of solid oxide fuel cells. Electrochem... 

Scheme 4.2 Preparation of sol-gel nanocoatings (Adapted from ref. 25, with permission.)...

The perfection of this nanocoating process following free shapes in three dimensions is nicely illustrated by the coating of nanowires. Uniform carbonaceous nanofibers of only some nanometers in diameter with high aspect ratio could be... 

Figure 11. Formation mechanism of an ultra-thin metal nanocoating in the channel of SBA-15 [64].

Recycling of plastic/glass/metal with nanocoating Recycling facility Air, soil... 

Kuncicky DM, Naik RR, Velev OD (2006) Rapid deposition and long-range alignment of nanocoatings and arrays of electrically conductive wires from tobacco mosaic virus. Small 2 1462-1466... 

Rudra JS, Dave K, Haynie DT (2006) Antimicrobial polypeptide multilayer nanocoatings. J Biomater Sci Polym Ed 17 1301-1315... 

Nowadays the core-shell (or nanocoating) technique is extensively applied to the synthesis of both semiconductor and insulating nanostructures for a variety of purposes. By modification of their nanostructure or surface, one can improve the quantum efficiency of lanthanide optical centers, and design biolabels. In addition, core-shell particles can be used as precursor to produce hollow spheres. 

It is possible to alter the intrinsic properties of materials by chemical nanocoating, which cannot be achieved by conventional methods. Generally the core-shell nanostructures are divided into two categories (1) lanthanides doped in the core (2) lanthanides doped in the shell. The former are synthesized in order to improve the quantum efficiency of lanthanide ions or design bio-labels, while the latter are meant for the study of surface modifications on the lanthanide luminescence or the synthesis of lanthanide-doped hollow nanospheres. 

It is noteworthy that the optical properties of the ZnO cores are not affected by the nanocoating process. Their emission spectrum in the UV range is the same as that of uncoated nanoparticles. 

Our own work on quantum dots was instigated by Tito Trindade (Universidade Aveiro), principally exploiting carbamato precursors initially developed by Azad Malik, this initial work was ably extended by Mark Green (Oxonica Ltd) and Neer-ish Revaprasasu (University of Zululand) and is now carried on by the team in the University of Manchester and NanoCo Ltd. Our work has been extensively supported by the EPSRC in the UK and our fruitful collaborations with South Africa have been made possible by the long term support of the Royal Society in London and the NRF in South Africa. 

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