Submit an Article
Become a reviewer
Vol 230
Pages:
107
Download volume:
RUS ENG
Geology

Volume and surface distribution of radiation defect in natural diamonds

Authors:
E. A. Vasilev1
A. V. Kozlov2
V. A. Petrovskii3
About authors
  • 1 — Saint-Petersburg Mining University ▪ Orcid
  • 2 — Saint-Petersburg Mining University
  • 3 — Institute of Geology of the Komi Science Center of the Ural Branch of the RAS
Date submitted:
2017-11-16
Date accepted:
2018-01-16
Date published:
2018-04-25

Abstract

In the following article, we have studied the variations of natural irradiation of diamond crystals. The natural diamonds in some cases show homogeneous green colour, caused by irradiation of the entire crystals volume. Radiation damage effects, produced by the low-radiation doses, are detected by the luminescence of the GR1 system. The high-radiation doses cause bluish hue, turning into a greenish colour, while the maximum level of volume irradiation produces the black crystals. The crystals with homogeneous volumetric black colour distribution were also studied. The major source of radiation in such cases may represent a local stream containing water rich in 222 Rn and its decay products. There is a review of the geological environment in which diamonds could be irradiated due to the decay of the 222 Rn containing in water.

10.25515/pmi.2018.2.107
Go to volume 230

References

  1. Зинчук Н.Н. Типоморфизм алмаза Сибирской платформы / Н.Н.Зинчук, В.И.Коптиль. М.: Недра, 2003. 603 с.
  2. Инфракрасная спектроскопия и внутреннее строение алмазов россыпи Ичетью (Средний Тиман, Россия) / Е.А.Васильев, В.А.Петровский, А.В.Козлов, А.В.Антонов // Записки Российского минералогического общества. 2017. № 2. С. 58-72.
  3. Николаенко В.А. Влияние интенсивности реакторного облучения на расширение кристаллической решетки алмаза / В.А.Николаенко, Е.А.Красиков // Атомная энергия. 2014. № 4. С. 223-230. DOI: 10.1007/s10512-014-9782-7
  4. О радиационном происхождении объемной зеленой окраски природных алмазов / С.В.Титков, А.И.Иванов, А.С.Марфунин, Л.В.Бершов, В.М.Кулаков, М.В.Чукичев // Доклады РАН. 1994. Т.335. № 4. С. 438-502.
  5. Смыслов А.А. Региональные прогнозно-металлогенические исследования на уран и их роль в формировании минерально-сырьевой базы атомной промышленности России / А.А.Смыслов, А.В.Козлов // Записки Горного института. 2011. Т. 194. С. 12-45.
  6. Akkerblom G. Mapping of groundwater radon potential / G.Akkerblom, J.Lindgren // Uranium exploration data and techniques applied to the preparation of radioelement maps: Proceedings of a Technical Committee meeting. Vienna, 1996. P. 237-255.
  7. Armitage M. Radioactive halos in a diamond // American Laboratory. 1993. N 18. P. 28-30.
  8. Balfour I. Famous Diamonds. Christie's Books, 1997. P. 320.
  9. Boyd S.R. Infrared absorption by the B nitrogen aggregate in diamond / S.R.Boyd, I.Kiflawi, G.S.Woods // Philosophical Magazine B. 1995. Vol. 72. P. 351-361. DOI: 10.1080/1364281950823908
  10. Boyd S.R. The relationship between infrared absorption and the A defect concentration in diamond / S.R.Boyd, I.Kiflawi, G.S.Woods // Philosophical Magazine B. 1994. Vol. 69. P. 1149-1153. DOI: 10.1080/01418639408240185
  11. Campbell B. Radiation Damage of Diamond by Electron and Gamma Irradiation / B.Campbell, A.Maiwood // Physica Status Solidi. 2000. N 1. P. 99-107. DOI: 10.1002/1521-396X(200009)
  12. Clark C.D. The absorption spectra of natural and irradiated diamonds / C.D.Clark, R.W.Ditchburn, H.B.Dyer // Proceedings Royal Society of London A. 1956. N 234. P. 363-381. DOI: 10.1098/rspa.1956.0040
  13. Davies G. Current problems in diamond: towards a quantitative understanding // Physica B. 1999. N 274. P. 15-23. DOI: 10.1016/S0921-4526(99)00398-1
  14. Diamond from Arkhangelsk diamondiferous province / V.K.Garanin, S.M.Bezborodov, K.V.Garanin, N.N.Golovin, O.V.Palazhchenko // Extended Abstracts and articles of 30th Gemmological Conference. Moscow, 2007. P. 39-41.
  15. Dishler B. Handbook of spectral lines in diamond. Berlin Heidelberg: Springer-Verlag, 2012. 467 p.
  16. Eaton-Magana S.C. Temperature effects on radiation stains in natural diamonds / S.C.Eaton-Magana, K.S.Moe // Diamond and Related Materials. 2016. Vol. 64. P. 130-142. DOI: 10.1016/j.diamond.2016.02.009
  17. El-Khayatt A.M. Radiation shielding of concretes containing different lime/silica ratios // Annals of Nuclear Energy. 2010. N 37. P. 991-995.
  18. Gauthier-Lafaye F. Natural fission reactors in the Franceville Basin, Gabo: a review of the conditions and results of a «critical event» in a geologic system / F.Gauthier-Lafaye, P.Holliger, P.L.Blanc // Geochimica et Cosmochimica Acta. 1996. N 23. P. 4831-4852. DOI p.10.1016/S0016-7037(96)00245-1
  19. Harris J.W. Diamond geology // The properties of natural and synthetic diamond / J.E.Field (ed). London: Academic Press, 1992. P. 345-393.
  20. Infrared absorption studies of neutron-irradiated type Ib diamond / Y.Mita, Y.Yamada, Y.Nisida, M.Okada, T.Nakashima // Physica B. 2006. Vol. 376. P. 288-291. DOI p.10.1016/j.physb.2005.12.074
  21. Internal radioactive haloes in diamond / M.J.Mendelssohn, H.J.Milledge, E.R.Vance, E.Nave, P.A.Woods // Industrial Diamond Review. 1979. Vol. 39. P. 31-36.
  22. International Nuclear Structure and Decay Data Network of the IAEA. URL:https//www-nds.iaea.org (date of access 15.01.2018).
  23. Kanaya K. Penetration and energy loss theory of electrons in solid targets / K.Kanaya, S.Okayama // Journal Physics D: Applied Physics. 1972. N 5. P. 43-58. DOI p.10.1088/0022-3727/5/1/308
  24. Mironov V.P. FTIR spectroscopy of annealing processes in neutron irradiated diamonds // Wide Bandgap Layers: Abstract Book 3rd International Conference on Novel Applications of Wide Bandgap Layers. Warsaw, 2001. P. 130-131. DOI p.10.1109/WBL.2001.946572
  25. Nikolaenko V.A. Effect of γ-irradiation on defect annealing in diamond / V.A.Nikolaenko, V.G.Gordeyev, V.I.Karpukhin // Radiation Effects and Defects in Solids. 1996. N 3. P. 173-182. DOI p.10.1080/10420159608211544
  26. Palmer D.V. Rate of production of radiation damage in diamond // Properties and growth of diamond / G.Davies (ed). London: INSPEC IEE, 1994. P. 143-152.
  27. Radio-colouration of diamond: a spectroscopic study / L.Nasdala, D.Grambole, M.Wildner, A.M.Gigler, T.Hainschwang, A.M.Zaitsev, J.W.Harris, J.Milledge, D.J.Schulze, W.Hofmeister, W.A.Balmer // Contributions to Mineralogy and Petrology. 2013. N 5. P. 843-861. DOI p.10.1007/s00410-012-0838-1
  28. The Diamond Deposits of Kalimantan, Borneo / L.K.Spencer, S.D.Dikinis, P.C.Keller, R.E.Kane // Gems and Gemology. 1988. N 2. P. 67-80.
  29. Vanse E. X-ray study of neutron irradiated diamonds // Journal Physics C: Solid State Physics. 1971. N 4. P. 257-262. DOI p.10.1088/0022-3719/4/3/001
  30. Vanse E.J. Possible origins of a-damage in diamonds from kimberlite and alluvial sources / E.J.Vanse, J.W.Harris, H.J.Milledge // Mineralogical Magazine. 1973. Vol. 39. P. 349-360.
  31. Woods G.S. Infrared absorption studies of the annealing of irradiated diamonds // Philosophical Magazine B. 1984. N 6. P. 673-688. DOI p.10.1080/1364281
  32. Zaitsev A.M. Optical properties of diamond: a data handbook. New York: Springer, 2001. 502 p.
Access statistics
Abstract Views
748
Full-Text Views
250
Cited
Scopus:
8
Crossref:
0
Cited By
1. Comparison of the I and IV Diamond Types (According to Orlov’s Classification) from the Snap Lake Deposit (Slave Craton, Canada). Doklady Earth Sciences. July 2023, Vol. 511, P. 537-542. DOI: 10.1134/S1028334X23600640 [Scopus]
2. Growth Pyramids of {110} Faces in Natural Diamonds. Geology of Ore Deposits. December 2022, Vol. 64, P. 670-675. DOI: 10.1134/S1075701522080086 [Scopus]
3. Growth of pyramids {110} in natural diamonds. Zapiski Rossiiskogo Mineralogicheskogo Obshchestva. 2021, Vol. 150, P. 127-133. DOI: 10.31857/S0869605521010068 [Scopus]
4. Identification of Type IIa Blue CVD Synthetic Diamonds from Huzhou SinoC Semiconductor Co. in China. Journal of Gemmology. September 2020, Vol. 37, P. 306-313. DOI: 10.15506/JoG.2020.37.3.306 [Scopus] (cited: 4)
5. Luminescence of natural diamond in the NIR range. Physics and Chemistry of Minerals. 1 July 2020, Vol. 47, DOI: 10.1007/s00269-020-01099-2 [Scopus] (cited: 4)
6. The story of one diamond: The heterogeneous distribution of the optical centres within a diamond crystal from the Ichetju placer, northern Urals. Mineralogical Magazine. 1 August 2019, Vol. 83, P. 515-522. DOI: 10.1180/mgm.2019.32 [Scopus] (cited: 9)
7. Luminescence of Plastically Deformed Diamond in the Range 800–1050 nm. Journal of Applied Spectroscopy. 15 July 2019, Vol. 86, P. 512-515. DOI: 10.1007/s10812-019-00850-0 [Scopus] (cited: 7)
8. The nature of the elongated form of diamond crystals from urals placers. Journal of Mining Institute. 2019, Vol. 239, P. 492-496. DOI: 10.31897/PMI.2019.5.492 [Scopus] (cited: 3)
Article Menu
Volume and surface distribution of radiation defect in natural diamonds

Similar articles

Improvement of the procedure of recruitment of personnel for hazardous work environment
2018 N. D. Tskhadaya, D. Yu. Zakharov
Estimation of the relation of strength and ultrasound speed in glass-reinforce plastic
2018 A. I. Potapov
Sulfidization of silver-polymetallic ores of «Goltsovoe» deposit for decreasing loss of silver in mill tailings
2018 L. V. Shumilova, O. S. Kostikova
Analyis of government support tools for mining companies in the Russian Arctic zone
2018 S. A. Lipina, L. K. Bocharova, L. A. Belyaevskaya-Plotnik
Theoretical aspects of the technical level estimation of electrical engineering complexes
2018 S. V. Kolesnichenko, O. V. Afanaseva
Peculiarities of formation and growth of nanodispersed intermetallic strengthening inclusions in rapidly-solidified alloys of Al–Mg–Zr–X-system
2018 D. I. Budelovskii, S. Yu. Petrovich, V. A. Lipin