Access the full text.
Sign up today, get DeepDyve free for 14 days.
V. Davydov, A. Rakhmanina, S. Rols, V. Agafonov, M. Pulikkathara, R. Wal, V. Khabashesku (2007)
Size-Dependent Phase Transition of Diamond to Graphite at High PressuresJournal of Physical Chemistry C, 111
(2019)
Highpressure, high-temperature synthesis of nanodiamond from adamantane, Inorg
(1999)
Synthesis of diamond from carbonaceous materials
E. Ekimov, O. Kudryavtsev, N. Mordvinova, O. Lebedev, I. Vlasov (2018)
High‐Pressure Synthesis of Nanodiamonds from Adamantane: Myth or Reality?, 4
R. Wentorf (1965)
The Behavior of Some Carbonaceous Materials at Very High Pressures and High TemperaturesThe Journal of Physical Chemistry, 69
S. Osswald, V. Mochalin, M. Havel, G. Yushin, Y. Gogotsi (2009)
Phonon confinement effects in the Raman spectrum of nanodiamondPhysical Review B, 80
(2019)
Unconventional synthesis of nano-and microcrystalline diamond under high static pressures
(2007)
Size-dependent phase transition of diamond to graphINORGANIC MATERIALS Vol. 56 No. 4 2020 CARBONIZATION OF BROMINATED ADAMANTANE AND NANODIAMOND 345 ite at high pressures
S. Stelmakh, K. Skrobas, S. Gierlotka, B. Palosz (2019)
Atomic structure of nanodiamond and its evolution upon annealing up to 1200 °C: Real space neutron diffraction analysis supported by MD simulationsDiamond and Related Materials
A. Onodera, K. Suito, Yasuhiro Morigami (1992)
High-Pressure Synthesis of Diamond from Organic Compounds, 68
K. Kondrina, O. Kudryavtsev, I. Vlasov, R. Khmelnitskiy, E. Ekimov (2018)
High-pressure synthesis of microdiamonds from polyethylene terephthalateDiamond and Related Materials, 83
G. Costa, O. Shenderova, V. Mochalin, Y. Gogotsi, A. Navrotsky (2014)
Thermochemistry of nanodiamond terminated by oxygen containing functional groupsCarbon, 80
E. Ekimov, A. Zoteev, N. Borovikov (2009)
Sintering of a nanodiamond in the presence of cobaltInorganic Materials, 45
A. Ferrari, J. Robertson (2004)
Raman spectroscopy of amorphous, nanostructured, diamond–like carbon, and nanodiamondPhilosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, 362
(2016)
The effect of molecular structure of organic compound on direct high-pressure synthesis of boron-doped nanodiamonds
A. Tiwari, J. Goss, P. Briddon, N. Wright, A. Horsfall, M. Rayson (2012)
Bromine functionalisation of diamond: An ab initio studyphysica status solidi (a), 209
E. Ekimov, O. Kudryavtsev, S. Turner, S. Korneychuk, V. Sirotinkin, T. Dolenko, A. Vervald, I. Vlasov (2016)
The effect of molecular structure of organic compound on the direct high‐pressure synthesis of boron‐doped nanodiamondphysica status solidi (a), 213
E. Ekimov, K. Kondrina, N. Mordvinova, Oleg Lebedev, D. Pasternak, I. Vlasov (2019)
High-Pressure, High-Temperature Synthesis of Nanodiamond from AdamantaneInorganic Materials, 55
(2015)
Highpressure synthesis of boron-doped ultrasmall diamonds from an organic compound, Adv
O. Shenderova, A. Shames, N. Nunn, M. Torelli, I. Vlasov, A. Zaitsev (2019)
Review Article: Synthesis, properties, and applications of fluorescent diamond particlesJournal of Vacuum Science and Technology. B, Nanotechnology & Microelectronics, 37
E. Ekimov, S. Lyapin, Y. Grigoriev, I. Zibrov, K. Kondrina (2019)
Size-controllable synthesis of ultrasmall diamonds from halogenated adamantanes at high static pressureCarbon
K. Kondo, S. Sawai, M. Akaishi, S. Yamaoka (1993)
Deformation behaviour of shock-synthesized diamond powder under high pressures and high temperaturesJournal of Materials Science Letters, 12
K. Skrobas, S. Stelmakh, S. Gierlotka, B. Palosz (2019)
A model of density waves in atomic structure of nanodiamond by molecular dynamics simulationsDiamond and Related Materials
E. Ekimov, O. Kudryavtsev, A. Khomich, O. Lebedev, T. Dolenko, I. Vlasov (2015)
High‐Pressure Synthesis of Boron‐Doped Ultrasmall Diamonds from an Organic CompoundAdvanced Materials, 27
—Dibromoadamantane, C10H14Br2, carbonization has been studied in detail at a pressure of 8 GPa and temperatures of up to 1700°C. The results demonstrate that, starting at dibromoadamantane decomposition temperatures in the range 600–700°C, the major solid carbonization product is nanodiamond. Relatively low, well-controlled synthesis parameters offer the possibility of controlling the size, morphology, and structure of nanodiamond.
Inorganic Materials – Springer Journals
Published: Apr 27, 2020
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.