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Synteettinen timantti (Finnish Wikipedia)

Analysis of information sources in references of the Wikipedia article "Synteettinen timantti" in Finnish language version.

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  • Suslick, Kenneth S et al.: Acoustic cavitation and its chemical consequences. Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, 1999, 357. vsk, nro 1751, s. 335–353. The Royal Society. doi:10.1098/rsta.1999.0330.
  • Khachatryan, A Kh et al.: Graphite-to-diamond transformation induced by ultrasound cavitation. Diamond and Related Materials, 2008, 17. vsk, nro 6, s. 931–936. Elsevier. doi:10.1016/j.diamond.2008.01.112.
  • Voropaev, SA et al.: Experimental study into the formation of nanodiamonds and fullerenes during cavitation in an ethanol-aniline mixture. Doklady Physics, 2014, 59. vsk, nro 11, s. 503–506. Springer. doi:10.1134/S102833581411007X.
  • Voropaev, SA et al.: Synthesis of diamondlike nanoparticles under cavitation in toluene. Doklady Physics, 2012, 57. vsk, nro 10, s. 373–377. Springer. doi:10.1134/S1028335812100047.
  • Stravato, A et al.: HVOF-sprayed nylon-11+ nanodiamond composite coatings: production & characterization. Journal of Thermal Spray Technology, 2008, 17. vsk, nro 5–6, s. 812–817. Springer. doi:10.1007/s11666-008-9253-6.
  • Kidalov, Sergey V & Shakhov, Fedor M: Thermal conductivity of diamond composites. Materials, 2009, 2. vsk, nro 4, s. 2467–2495. Molecular Diversity Preservation International. doi:10.3390/ma2042467.
  • Albrecht, Andreas et al.: Self-assembling hybrid diamond — biological quantum devices. New Journal of Physics, 2014, 16. vsk, nro 9, s. 093002. IOP Publishing. doi:10.1088/1367-2630/16/9/093002.
  • Shugalei, IV et al.: Biological activity of detonation nanodiamond and prospects in its medical and biological applications. Russian Journal of General Chemistry, 2013, 83. vsk, nro 5, s. 851–883. Springer. doi:10.1134/S1070363213050010.
  • Xi, Guifa et al.: Convection-enhanced delivery of nanodiamond drug delivery platforms for intracranial tumor treatment. Nanomedicine: Nanotechnology, Biology and Medicine, 2014, 10. vsk, nro 2, s. 381–391. Elsevier. doi:10.1016/j.nano.2013.07.013.
  • Wang, Xin et al.: Epirubicin-Adsorbed Nanodiamonds Kill Chemoresistant Hepatic Cancer Stem Cells. ACS nano, 2014. ACS Publications. doi:10.1021/nn503491e.

gia.edu

google.com

htracyhall.org

  • Bundy, F. P. & Hall, H. T. & Strong, H. M. & Wentorf, R. H.: Man-made diamonds. Nature, 1955, 176. vsk, nro 51. Artikkelin verkkoversio. (Arkistoitu – Internet Archive)
  • Hall, H. Tracy: A SUCCESSFUL DIAMOND SYNTHESIS. G.E. Research Laboratory Report No, 1064. General Electric, 1955. Memo Report C-55-3. Teoksen verkkoversio. (Arkistoitu – Internet Archive)
  • Hall, H Tracy: The synthesis of diamond. Journal of Chemical Education, 1961, 38. vsk, nro 10, s. 484. Artikkelin verkkoversio. (Arkistoitu – Internet Archive)

jckonline.com

kitco.com

researchgate.net

  • Angus, John C. & Hayman, Cliff C.: Low-Pressure, Metastable Growth of Diamond and "Diamondlike" Phases. Science, 1988, 241. vsk, s. 913–921. Artikkelin verkkoversio.

web.archive.org