Hostname: page-component-848d4c4894-m9kch Total loading time: 0 Render date: 2024-05-14T00:06:18.326Z Has data issue: false hasContentIssue false
  • English
  • Français

Yimengite of K–Ti metasomatic origin in kimberlitic rocks from Venezuela

Published online by Cambridge University Press:  05 July 2018

Peter H. Nixon  and
Eric Condliffe
Peter H. Nixon
Affiliation:
Department of Earth Sciences, The University, Leeds LS2 9JT, U.K.
Eric Condliffe
Affiliation:
Department of Earth Sciences, The University, Leeds LS2 9JT, U.K.
Get access Rights & Permissions [Opens in a new window]

Abstract

This second recorded occurrence of yimengite, K(Cr, Ti, Fe, Mg, Al)12O19, is in a Precambrian kimberlitic sill in the Guaniamo District of Bolivar Province, Venezuela. The paragenesis is similar to that of the type area in Shandong Province, China, where the mineral is in kimberlite dykes. At both localities the yimengite is a K, Ti-bearing metasomatic product of chromium-rich spinel. In the Venezuela rocks the spinels are of the type occurring both as diamond inclusions and as a component of diamond-related Cr-rich garnet harzburgite mantle xenoliths. Yimengite contains significant amounts of barium (up to 3.4wt.% BaO) and is thus transitional to the recently described mineral hawthorneite, Ba(Cr, Ti, Fe, Mg)12O19. Both members are part of a suite of titanate minerals found in kimberlites and their inclusions which has been described by Haggerty and coworkers; they formed as a result of mantle metasomatism generated by K- and Ba-rich fluids. In Venezuela, metasomatism of this type would appear to be deeper than that usually recorded, namely in the basal lithosphere. The metasomatizing fluids are derived from the underlying, more oxygenated asthenosphere. The host kimberlitic rocks are not significantly enriched in K and Ba, but these elements are concentrated in later micaceous dykes which are conjectured to have been generated within similar metasomatized mantle.

Keywords

yimengitehawthorneitespinelkimberlitic rocksVenezuela
Type
Non-silicate Mineralogy
Information
Mineralogical Magazine , Volume 53 , Issue 371 , June 1989 , pp. 305 - 309
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1989

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bergman, S. C. (1987) Lamproites and other potassiumrich igneous rocks: a review of their occurrence, mineralogy and geochemistry. In The alkaline igneous rocks (Fitton, J. G. and Upton, B. G. J., eds.). Special Publ., Geol. Soc., London, 30, 103-90.Google Scholar
Boyd, F. R. and Gurney, J. J. (1982) Low-calcium garnets: keys to craton structure and diamond crystallization. Carnegie Inst. Washington Yearb. 81, 261-7.Google Scholar
Boyd, F. R. and Gurney, J. J., Jones, R. A., and Nixon, P. H. (1983) Mantle metasomatism: the Kimberley dunites. Ibid. 82, 330-6.Google Scholar
Zhenxin, Dong, Jianxiong, Zhou, Qi, Lu and Zhizhong, Peng (1983) Yimengite, K(Cr, Ti, Fe, Mg)12O19, a new mineral from China. Kexue Tongbao, 15, 932-6 (in Chinese). Also (1986) Sci. Sinica (Series B), 29, 920-3.Google Scholar
Erlank, A. J., Waters, F. G., Hawksworth, C. J., Haggerty, S. E., Atlsopp, H., Rickard, R. S., and Menzies, M. (1987) Evidence for metasomatism in peridotite nodules from the Kimberly pipes, South Africa. In Mantle Metasomatism (Hawksworth, C. J. and Menzies, H., eds.). Academic Press, 221331.Google Scholar
Grey, I. E., Madsen, I. C., and Haggerty, S. E. (1987) Structure of a new upper-mantle magnetoplumbitetype phase, Ba(Ti3Cr4Fe4Mg)O19 . Am. Mineral 72, 633-6.Google Scholar
Haggerty, S. E. (1986) Diamond genesis in a multiplyconstrained model. Nature, 320, 34-8.CrossRefGoogle Scholar
Haggerty, S. E. (1987) Metasomatic mineral titanates in upper mantle xenoliths. In Mantle Xenoliths (Nixon, P. H., ed.). J. Wiley and Sons Ltd., Chichester, 671-90.Google Scholar
Haggerty, S. E., Smyth, J. R., Ertank, A. J., Rickard, R. S., and Danchin, R. V. (1983) Lindsleyite (Ba) and Mathiasite (K): two new chromium titanites in the crichtonite series from the upper mantle. Am. Mineral. 69, 494-505.Google Scholar
Haggerty, S. E., Erlank, A. J., and Grey, I. E. (1986) Metasomatic mineral titanate complexing in the upper mantle. Nature, 319, 761-3.CrossRefGoogle Scholar
Haggerty, S. E., Grey, I. E., Madsen, I. C., Criddle, A. J., Stanley, C. J., and Erlank, A. J, (1989) Hawthorneite, Ba(Ti3Cr4Fe4Mg)O19: a new metasomatic magnetoplumbite- type mineral from the upper mantle. Am. Mineral. 74 (in press).Google Scholar
Harte, B. (1987) Metasomatic events recorded in mantle xenoliths: an overview. In Mantle Xenoliths (Nixon, P. H., ed.). J. Wiley and Sons Ltd., Chichester, 626-40.Google Scholar
Jianxiong, Z., Guiojie, Y., and Jianhong, Z. (1984) Mathiasite in a kimberlite from China. Acta Mineral. Sinica, 9, 193-200.Google Scholar
Meyer, H. O. A. (1985) Genesis of diamond: a mantle saga. Am. Mineral. 70, 344-55.Google Scholar
Mitchell, R. H., and Lewis, R. D. (1983) Priderite-bearing diopside-titanian potassian richterite xenoliths from the Prairie Creek mica peridotite, Arkansas. Can. Mineral. 21, 59-64.Google Scholar
Nixon, P. H., and Davies, G. R. (1987) Mantle xenolith perspectives. In Mantle Xenoliths (Nixon, P. H., ed.). J. Wiley and Sons Ltd., Chichester, 741-56.Google Scholar
Nixon, P. H., and Davies, G. R., van Calsteren, P. W. C., Boyd, F. R., and Hawsworth, C. J. (1987) Harzburgites with garnets of diamond facies from southern African kimberlites. Ibid. 523-33.Google Scholar
Zhizhong, Peng, and Qi, Lu (1985) The crystal structure of yimengite. Sci. Sinica (Series B), 28, 882-7.Google Scholar
Sobolev, N. V., Lavrent'yev, Yu. G., Pokhilenko, N. P., and Usova, L. V. (1973) Chrome-rich garnets from the kimberlites of Yakutia and their paragenesis. Contrib. Mineral Petrol. 40, 39-52.CrossRefGoogle Scholar