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Monodispersed Nanodiamonds Produced by Laser Ablation

Published online by Cambridge University Press:  30 July 2012

Boris Zousman  and
Olga Levinson
Boris Zousman
Affiliation:
Ray Techniques Ltd 4-2, High-Tech village, The Hebrew University of Jerusalem, P.O.B. 39162, 91391, Israel
Olga Levinson
Affiliation:
Ray Techniques Ltd 4-2, High-Tech village, The Hebrew University of Jerusalem, P.O.B. 39162, 91391, Israel
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Abstract

Nanodiamond powder (ND) has become one of the most promising and well-studied nanomaterials applied in various fields of science, technology and medicine. Recent achievements in the development of advanced ND applications present new demands to ND quality: purity, homogeneity of primary particle dimensions and surface area chemistry. ND produced by state-of-the-art technology of detonation synthesis doesn’t meet requirements for biomedical and optical applications. Therefore, alternative methods of ND synthesis from pure carbon raw materials enabling to control the process are of especial importance.

The novel technology for ND laser synthesis has been developed by Ray Techniques Ltd. The method is based on high-intensive laser radiation treatment of the specially prepared target containing non-diamond carbon soot and hydrocarbons, placed in a liquid media. As a result, carbon atoms collect to form a cubic diamond crystalline lattice. To reach that, the appropriate parameters of the laser radiation, special composition of the target and the liquid media, as well as the treatment procedures were determined. The “winning” combination of these factors enables to obtain pure nanodiamonds (RayND). In contrast to the existing technology, the RT method is highly controllable, environment-friendly and efficient.

RayND obtained under different conditions were studied and compared with detonation ND currently available at the market. It is proved that the higher level of purity and homogeneity of RayND constitutes significant advantages for most ND applications. Using RayND opens new frontiers in biomedicine (drug- and gene-delivery and bio-imaging agents), electronic industry (abrasives for wafer polishing, heat-conductive electrical-insulating compounds, CVD coatings, emitters, etc) and optics (displays, protective transparent films, laser lenses, optical windows and filters).

Keywords

nanostructurediamondlaser ablation
Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 1452: Symposium FF – Nanodiamond Particles and Related Materials--From Basic Science to Applications , 2012 , mrss12-1452-ff07-06
Copyright
Copyright © Materials Research Society 2012

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References

1. Ultrananocrystalline diamond: synthesis, properties and applications; Shenderova, O. and Gruen, Dieter, 2006 Google Scholar
2. Nanodiamond Particles: Properties and Perspectives for Bioapplications. Schrand, Amanda, Hens, Suzanne Ciftan and Shenderova, Olga; Solid State and Materials Science; 2009 Google Scholar
3. New prospects and frontiers of nanodiamond clusters; Baidakova, M, Vul, A; J. Phys. D: Appl. Phys. 2007 Google Scholar
4. Detonation nanodiamonds: problems and prospects; Danilenko, V.V.. Superhard Materials. 2010, N5Google Scholar
5. Growth of diamond nanocrystals by pulsed laser ablation of graphite in liquid; Yang, L., May, P.W., Yin, L., Smith, J.A., Rosser, K.N., Diamond & Related Materials, 16, 2007 Google Scholar
6. Laser ablation in liquids: Applications in the synthesis of nanocrystals; Yang, G.W.; Progress in Materials Science, 52, 2007 Google Scholar
7. Nanodiamond synthesis by pulsed laser ablation in liquids; Amans, D., Chenus, A., Ledoux, G., Dujardin, C., Reynaud, C., Sublemontier, O., Masenelli-Varlot, K., Guillois, O.; Diamond & Related Materials, 18, 2009 Google Scholar
8. Factors affecting DNP NMR in Polycrystalline Diamond Samples; Casabianca, Leah B., Shames, Alexander I., Panich, Alexander M., Shenderova, Olga, and Frydman, Lucio; J. Phys. Chem. C, 2011 Google Scholar
9. Magnetic resonance study of nanodiamonds prepared by laser-assisted technique; Panich, A., Shames, A., Zousman, B, Levinson, O.; Diamond and related materials, 2012 Google Scholar