Models
of diamond generation in different geodynamic environments
Lapin A.V.* Belov S.V.**
*
In recent years wide development of non-kimberlitic diamondiferous
rocks of orogenic foldbelts was identified in zones of continental collision
(Tjen Shan, Tibet, Gibraltar Arc, etc.) and accretion-collision zones of active
continental margins (Kamchatka Peninsula, Koriak
Upland, Japanese Islands, etc.)Á as well as in ultrametamorphic rocks, characterized by
intensive deformation with abundance of blastomylonitic and
blastocataclastiticÁ textures (Northern
Kazakhstan, the Urals,
Diamondiferous kimberlitic rocks, predominant in the area of ancient cratons donôt play any significant part in mobile zones and they areÁ replaced by various non-kimberlitic sources of diamonds. In orogenic foldbelts in zones of continental collisionÁ non-kimberlitic diamondiferous rocks are presented by dikes of alkaline lamprophyres like minettes and kamptomonochiquites, pipes of alkaline basaltoids, dikes andÁ pipes of lamproitelike rocks, dikes of picrites, pipes and dikes of original carbonatitelike rocks of complex silicate- carbonate composition, ultrabasic rocks of intrusions, belonging to ophiolitic and platinum bearing formations. In accretion-collision zonesÁ of active continental margins, diamondiferous non-kimberlitic rocks are established in volcanic ultrabasicÁ rocks of the comatiite type, basalts and melabasalts, ultramafites in massifsÁ of ophiolitic and platinum bearing formations, lamprophyric dikes. In ultrametamorphite belts, typical of collision fold zones, diamonds are determined in gneisses, eclogites and their metasomatised varieties.
Taking into account rather individual position of kimberlites, typical of stable ancient cratons, often attempts to explain non-kimberlitic diamond mineralisation ofÁ igneous and metamorphic rocks with the help of model common with kimberlites are not efficient. Thus, a problem arises about possible conditions for diamonds generation, that differ from traditional kimberlitic diamondÁ formation.
According to the modern data, the areas of kimberlitic diamondiferous rocks abundance are limited by ancient Archean cratons, i. e. areas of early stabilization, which during the long period existed under conditions of quiet amagmatic regimes. These conditions are in agreement with low value of thermal flow and weakÁ penetrability of the lithosphere for abyssal fluids and melts. Kimberlites, as a rule, donôt demonstrate apparent connection with large units of break tectonics of the lithosphere ( rifts, zones of abyssal fractures, etc.)Á and in respect of geologic-tectonical position they behave as most abyssal formations that are initiated by processes generated in sublithosphere zones of the mantle, perhaps, low parts of the upper mantle and the intermediate zone. Thus, the diamond in kimberlites, the stability of which is determined by significant lithostatic pressure and low thermal gradients, is accompanied by abyssal mantle paragenesis, including such typical accessory minerals as pyrope, picroilmenite, chrome diopside and others.
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁ In contrast, occurrences of
non-kimberlitic diamondiferous igneous and metamorphic rocks are, with rare
exception, confined to the most geodynamically active lithosphere blocks
existing under conditions of stressed deformation state. In this connection,
the model of non-kimberlitic diamondiferous rocks generation should take into
account characteristic features of stressed-deformation state of the
lithosphere, typical of orogenic foldbelts zones of the continental collision
and accretion-collision active continental margins.
According to ±.V. Gzovsky (1975) the
values of the highest tangential stresses can significantly increase
lithostatic load and come to 1,47 GPa atÁÁ depth up to
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁ Based on the data on
physical-chemical geomechanics, the most favorable environmentÁ for diamond generation and phase
transition of graphite-diamond appears to be created in combination of
compression and shift, when chemical reactions are accelerated and intensified.
Similar environment often occurs in abyssal tectonic zones confined to
ultrametamorphic beltsÁ
(Kokchetav block, the Urals, etc.) and
in orogenic zones of the continental collision (Tjen Shan, Tibet and oth.),
where stressed-deformation state of the lithosphere is often accompanied by
magma formation, as well as in accretion- collision zones of active continental
margins, where non-kimberlitic rocks can be controlled by seismofocal zones of
focuses of paleoearthquake concentration.
With respect of different models of diamondiferous rocks formation in different geodynamic environments, estimation-prospecting criteria and methods , directed to kimberlitic diamondiferous rocks, are rather rarely used for diamond prospecting in mobile zones, collision folded systems, and active marginal zones of continents. Under these conditions, both composition of non-kimberlitic diamond sources and paragenesis of its accessory minerals can significantly vary depending on the composition of diamond producing substrate. Typical diamond minerals- indicators(pyrope and oth.) occur only in lamproitelike rocks and ultrahigh pressure ultrabasic massifs.Á In different types of rocksÁ diamonds are always accompanied by moissanite and other carbides, native metals (Au, Ag, Pt, Pb, Cu and oth.) and their alloys, graphite; coesitic pseudomorphs of quartz are often present.
ÁThus, one of the most important results of the new data on occurrences of non-kimberlitic diamondiferous rocks is the variety of potential diamond sources and models of diamond formation as well as their dependence on geodynamic regimes, peculiar to these or those lithosphere segments. Obviously, the above should be taken into account in estimation and prospecting for diamonds in outer craton environment.
References:
Belov S.V., Lapin
A.V. and oth. Metallogeny of Platform Magmatism (carbonatites, kimberlites, trappes).
Kaminsky F.V.
Non-Kimberlitic Diamondiferous Igneous Rocks: 25 Years on. // Journ. Geol. Soc. of
Gzovsky M.V. The basics of Tectonophysics. M. Nauka.
1975. 535 p. (in Russan).
Kropotkin P. N.
Tectonic Stresses in the Earthôs Crust // Geotectonics.
µ2.1996. p.3-15. (in
Russian).
Filatova V.T. and oth. Tectonophysics of
Intraplate Collision // Geology and Mineral Resources of the