Abstract
The study of the Bol’shaya Tagna alkaline-carbonatite massif and adjacent areas was focused on the mineral and chemical compositions of minerals, the distribution of petrogenic and trace elements in pyroxene-free alkaline picrites in veins and dikes dated at the late Riphean (circa 645 Ma), and comparison with the Bushkanai kimberlite-picrite dike. Phenocrysts in the pyroxene-free picrites are represented by olivine (replaced with serpentine) and phlogopite; the bulk is formed by serpentine, phlogopite, monticellite, calcite, etc .; xenocrysts of pyrope and chrome diopside are absent. Phlogopite and Cr-spinel from the picrites are chemically similar to these minerals in kimberlites, but the evolution of the spinel compositions corresponds to the titanomagnetite trend; monticellite is depleted in forsterite (Mg 2 SiO 4 ). The rocks contain strontianite, burbankite, titanium andradite, calcirtite and Mn-ilmenite, which are not typical of kimberlites, but are inherent in carbonate-bearing ultramafic lamprophyres, ayllikites. The pyroxene-free picrites have low contents (wt %) of SiO 2 (28.4‒33.2), Al 2 O 3 (3.2‒5.6), and Na 2 O (0.01‒0.05); relatively high contents of TiO 2 (2.0‒3.3), and К 2 О (0.45‒1.33); varying contents of MgO (16.1‒24.1), СаО (12.9‒22.8), СО 2 (1.1‒12.2), Ni (260‒850 ppm), and Cr (840‒2200 ppm); and Mg#=0.73‒0.80. The contents of Th, U, Nb, Ta, La, and Ce in the veins are approximately two orders higher than those in the primitive mantle; the spectra of trace elements differ from the spectra of the South African and Yakuian kimberlites. In the pyroxene-free picrites and the rocks of the Bushkanai dike, the Nb/U, Nb/Th, Th/Ce, La/Nb, and Zr/Nb ratios are similar to those in ocean island basalts (OIB) and thus give evidence of the leading contribution of the recycled component into the source melt. In experiments conducted to investigate melting of carbonated garnet lherzolite, the pyroxene-free alkaline picrites melted at 5–6 GPa.
Highlights
adjacent areas was focused on the mineral and chemical compositions of minerals
trace elements in pyroxene-free alkaline picrites in veins and dikes dated at the late Riphean
Phenocrysts in the pyroxene-free picrites are represented by olivine
Summary
Дайки и жилы пикритовых пор фиритов (беспироксеновых щелочных пикритов, или кимберлитоидов [Petrographic Code ..., 2008]) прорыва ют ийолиты и сиениты, а по взаимоотношениям с карбонатитами выделяются интра- и послекарбонатитовые тела [Frolov, Belov, 1999]. Зерна клинопироксена величиной до 1 см имеют сглаженно-округлую, реже угловатую форму, оливин замещен серпентином, вкрапленники слюды достигают 2 см. 3, д) в количестве 25–30 % присутствуют вкрапленники флогопита величиной до [2–3] мм, частич но или полностью замещенные хлоритом, но преиму щественно слюда находится в основной массе. В кимберлите Бушканайской дайки клинопироксен представлен хромдиопсидом, близким по химическому составу к клинопироксену из оранжеи тов Серпентин из псевдоморфоз по оливину и основ ной массы имеет довольно однородный химический состав: XMg варьируется в основном от 0.92 до 0.99; со держание Al2O3 составляет до 3.9 мас. Флогопит из пикритов содержит больше Al2O3 (14.3‒16.4 мас. %), TiO2 (1.9‒9.0 мас. %) и, в целом, менее магнезиальный, XMg=0.74‒0.87; флогопит (а) 51
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