Composition of Hydrocarbons in Synthetic Diamonds Grown in a FeNiC System (according to Gas ChromatographyMass Spectrometry Data)

Tomilenko A.A.; Bul'bak T.A.; Chepurov A.I.; Sonin V.M.; Zhimulev E.I; Pokhilenko N.P.

doi:10.1134/S1028334X18080111

Инд. авторы:	Tomilenko A.A., Bul'bak T.A., Chepurov A.I., Sonin V.M., Zhimulev E.I, Pokhilenko N.P.
Заглавие:	Composition of Hydrocarbons in Synthetic Diamonds Grown in a FeNiC System (according to Gas ChromatographyMass Spectrometry Data)
Библ. ссылка:	Tomilenko A.A., Bul'bak T.A., Chepurov A.I., Sonin V.M., Zhimulev E.I, Pokhilenko N.P. Composition of Hydrocarbons in Synthetic Diamonds Grown in a FeNiC System (according to Gas ChromatographyMass Spectrometry Data) // Doklady Earth Sciences. - 2018. - Vol.481. - Iss. 2. - P.1004-1007. - ISSN 1028-334X. - EISSN 1531-8354.
Внешние системы:	DOI: 10.1134/S1028334X18080111; РИНЦ: 35719870; SCOPUS: 2-s2.0-85052846051; WoS: 000443557400008;
Реферат:	eng: The first data of chromatographymass spectrometry analysis of volatiles from crystals of synthetic diamonds grown in a FeNiC system at 1350-1400 degrees C and 5.5-6.0 GPa are presented. The composition of the fluid in equilibrium with the metal-carbon melt is determined, and a comparative estimation for the compounds of different hydrocarbons and their derivatives is made. It is shown that a significant role in these processes is played by high-molecular-weight hydrocarbons; and the total share of hydrocarbons and their derivatives in the fluid compounds can exceed 86%.
Ключевые слова:	AGES; MANTLE; INCLUSIONS; MASS SPECTROMETRY; VOLATILE COMPONENTS; YAKUTIAN KIMBERLITES; CRYSTALLIZATION; GPA;
Издано:	2018
Физ. характеристика:	с.1004-1007
Цитирование:	1. E. M. Smith, S. B. Shirey, F. Nestola, E. S. Bullock, J. Wang, S. H. Richardson, and W. Wang, Science 354, 1403–1405 (2016) 2. A. A. Tomilenko, A. L. Ragozin, V. S. Shatsky, and A. P. Shebanin, Dokl. Earth Sci. 379 (1), 571–574 (2001) 3. A. A. Tomilenko, S. V. Kovyazin, L. N. Pokhilenko, and N. V. Sobolev, Dokl. Earth Sci. 426 (4), 695–698 (2009) 4. N. V. Sobolev, A. M. Logvinova, E. N. Fedorova, L. I. Luk’yanova, R. Wirth, A. A. Tomilenko, T. A. Bul’-bak, V. N. Reustsky, and E. S. Efimova, in Proc. AGU Fall Meet. (San Francisco, CA, December 14–18, 2015) 5. A. A. Tomilenko, T. A. Bul’bak, L. N. Pokhilenko, D. V. Kuzmin, and N. V. Sobolev, Dokl. Earth Sci. 469 (1), 690–694 (2016) 6. A. A. Tomilenko, T. A. Bul’bak, M. O. Khomenko, D. V. Kuzmin, and N. V. Sobolev, Dokl. Earth Sci. 468 (2), 626–632 (2016) 7. A. A. Tomilenko, A. I. Chepurov, A. I. Turkin, A. P. Shebanin, and N. V. Sobolev, Dokl. Earth Sci. 353 (2), 247–250 (1997) 8. A. A. Tomilenko, A. I. Chepurov, Y. N. Pal’yanov, A. P. Shebanin, and N. V. Sobolev, Eur. J. Mineral. 10 (6), 1135–1141 (1998) 9. A. I. Chepurov, I. I. Fedorov, and V. M. Sonin, Geol. Geofiz. 39 (2), 234–244 (1998) 10. E. I. Zhimulev, A. I. Chepurov, E. F. Sinyakova, V. M. Sonin, A. A. Chepurov, and N. P. Pokhilenko, Geochem. Int. 50 (3), 205–217 (2012) 11. A. G. Sokol, A. A. Tomilenko, T. A. Bul’bak, G. A. Palyanova, I. A. Sokol, and Y. N. Palyanov, Sci. Rep. 7, 706 (2017). doi doi 10.1038/s41598-017-00679-7 12. V. M. Sonin, T. A. Bul’bak, E. I. Zhimulev, A. A. Tomilenko, A. I. Chepurov, and N. P. Pokhilenko, Dokl. Earth Sci. 454 (1), 32–36 (2014) 13. E. I. Zhimulev, V. M. Sonin, T. A. Bul’bak, A. I. Chepurov, A. A. Tomilenko, and N. P. Pokhilenko, Dokl. Earth Sci. 462 (1), 527–532 (2015) 14. A. A. Tomilenko, A. I. Chepurov, V. M. Sonin, T. A. Bul’bak, E. I. Zhimulev, A. A. Chepurov, T. Yu. Timina, and N. P. Pokhilenko, High Temp.—High Pressures 44 (6), 451–465 (2015) 15. A. G. Sokol, Y. N. Palyanov, A. A. Tomilenko, T. A. Bul’bak, and G. A. Palyanova, Earth Planet. Sci. Lett. 460, 234–243 (2017)