Your search keyword '"I.R. Prokop’ev"' showing total 5 results

1. Mineralogical and Geochemical Features and Formation Conditions of the Tardan Gold–Sulfide–Quartz Deposit (Northeastern Tuva)

Author

I.R. Prokop’ev, N.N. Ankusheva, Anna A. Redina, and R.V. Kuzhuget

Subjects

chemistry.chemical_classification, Geophysics, Sulfide, chemistry, Geochemistry, Geology, 010503 geology, 010502 geochemistry & geophysics, 01 natural sciences, Quartz, 0105 earth and related environmental sciences

Abstract

—We studied the mineralogical and geochemical features and formation conditions of productive mineral assemblages of the Tardan gold–sulfide–quartz deposit located in the endo-/exocontact zone of the Kopto–Bai-Syut gabbro-diorite–plagiogranite pluton of the Early Ordovician Tannu-Ola complex (O1tn). Postskarn mineralization of vein–dissemination type in skarns, quartz diorites, and carbonate rocks is limited by tectonic crushing zones and conjugated with beresitization and listwanitization of the ore-bearing rocks. Mineralogical and geochemical research has shown the formation of ultrahigh-fineness (986–952‰) and high-fineness (947–918‰) gold at the first productive gold–quartz–calcite substage, of high-fineness gold (918–904‰) → medium-fineness gold (896–809‰) → low-fineness gold (798–756‰) ± hessite Ag2Te ± volynskite AgBiTe2 at the second productive gold–telluride–sulfide–quartz–carbonate substage, and of medium-fineness gold (897–802‰) → low-fineness gold (799–717‰) → electrum (691–612‰) → mercurian electrum (471–451‰) ± hessite Ag2Te ± acanthite Ag2S ± matildite AgBiS2 at the third productive gold–sulfosalt–sulfide–quartz substage. High- and medium-fineness gold prevails in the ores, ultrahigh- and low-fineness gold is subordinate, and electrum and mercurian electrum are scarce. The fineness of native gold in the ores varies from 451 to 986‰, averaging 858‰. The productive mineral assemblages of the Tardan deposit formed from aqueous fluids containing Mg, Na, and K chlorides (salinity of 6.1–12.9 wt.% NaCl eq.), with a decrease in the mineral formation temperature from 380 to 150 ºC and variations in fO2, fS2, fSe2, and fTe2.

Published

2020

2. 40Ar/39Ar Geochronology of Alkaline Rocks of the Inagli Massif (Aldan Shield, southern Yakutia)

Author

A.G. Doroshkevich, T.V. Svetlitskaya, A.V. Ponomarchuk, and I.R. Prokop’ev

Subjects

geography, Geophysics, geography.geographical_feature_category, Shield, Geochronology, Geochemistry, Geology, Massif

Abstract

—The Inagli zoned ring massif is located in the Central Aldan ore district. The close localization of ultrabasic and alkaline potassic rocks, magmatism, and mineralization (platinum, gems Cr-diopside, and vermiculite) make this object unique from both geological and economic perspectives. Formation of alkaline rocks in the Inagli massif was related to the Mesozoic tectonomagmatic activation of the Aldan Shield and occurred in several stages. Intrusion of clinopyroxenites took place no later than 145.8 ± 3.2 Ma, whereas most of alkaline rocks of the ring framing formed at 133–128 Ma. The feldspar-Cr-diopside-mica veins in the dunite core are dated at 133.4 ± 1 Ma.

Published

2019

3. The role of chloride-carbonate melts in the formation of sideritic carbonatites of the KARASUg FE-F-REE deposit (Tyva Republic, Russia)

Author

A. A. Borovikov, I.R. Prokop’ev, G. G. Pavlova, and Alexander S. Borisenko

Subjects

Geochemistry, Mineralogy, engineering.material, Fluorite, chemistry.chemical_compound, chemistry, Earth and Planetary Sciences (miscellaneous), engineering, Carbonatite, General Earth and Planetary Sciences, Carbonate, Halite, Fluid inclusions, Ankerite, Quartz, Geology, Melt inclusions

Abstract

The authors have studied melt-fluid and fluid inclusions in quartz and fluorite of sideritic and ankerite-calcitic carbonatites of the Karasug ore field, as well as melt inclusions in apatite from granosyenites. The content of salt and fluid components in brine-melt inclusions was evaluated on the basis of the thermodynamic data, the calculations of volumes and densities of the solid phases, a solution of about 50% concentration, and the gas phase of the inclusions, as well as the results of the LA-ICP-MS analysis. The content of salt phases, the solution, and the gas phase amounted to 85–70, 10–25, and about 5% of the inclusion substance, respectively. The total percentage of salt and fluid components (H2O and CO2) amounted to 90–80 and 10–20 wt %, respectively. The fraction of a carbonate constituent in the inclusions was as high as 45–50% and over in ankerite-calcite carbonatites and about 15 wt % in sideritic carbonatites. The 117.2 ± 1.3 Ma age of these carbonatites by 40Ar/39Ar, along with other datings for this area, shows that their formation was associated with a manifestation of the Cretaceous alkaline-mafic magmatism (117–120 Ma). The presented model of the formation of carbonatites is in agreement with the sequence of the development of magmatic processes and mineralization in this area. The model is also confirmed by the results of the studies of melt and fluid inclusions in minerals.

Published

2014

4. Oxidized magmatogene fluids: metal-bearing capacity and role in ore formation

Author

G. G. Pavlova, Nikolay V. Vladykin, Alexander S. Borisenko, A.A. Borovikov, E.A. Vasyukova, Alexey Ragozin, and I.R. Prokop’ev

Subjects

Mineralization (geology), Inorganic chemistry, Geochemistry, Geology, Metallogeny, Metal, chemistry.chemical_compound, Igneous rock, Geophysics, chemistry, visual_art, visual_art.visual_art_medium, Fluid inclusions, Bearing capacity, Sulfate, Melt inclusions

Abstract

Based on study of fluid and melt inclusions in minerals from igneous rocks and associated ore-metasomatic objects, we consider the formation conditions of oxidized fluids produced at the final stages of differentiation of alkali-basic, alkaline, lamproitic, and some granitoid melts. These fluids are characterized by wide variations in composition, concentrations, and physicochemical parameters (P, T, Eh, pH, etc.) and are of sulfate-chloride, sulfate-carbonate, sulfate-fluoride, fluoride-sulfate, essentially sulfate, and other types. The specific composition of these magmatogene fluids showing a high extractive power favors the effective removal of ore-forming elements (Fe, Mn, Co, N, Ag, Cu, Pb, Zn, Mo, W, Bi, U, REE, etc.) from melt and their trapping from the host rocks. The set of these elements is determined by P-T-X-parameters, conditions of fluid separation from melts, composition of fluid-generating magmas, and geochemical composition and metal-bearing capacity of rocks through which the fluids migrate. These factors significantly determine the metallogeny of alkaline, alkali-basic, and some granitoid complexes and associated mineralization.

Published

2011

5. Petrology and geochemistry of gabbro and picrites from the Altai collisional system of Hercynides: Evidence for the activity of the Tarim plume

Author

Andrey E. Izokh, I.R. Prokop’ev, Sergey S. Lobanov, S. V. Khromykh, A. V. Travin, Alexander Vladimirov, E. Azimbaev, and Томский государственный университет Геолого-географический факультет Научные подразделения ГГФ

Subjects

геохимия, Igneous activity, Gabbro, габбро-пикритовые ассоциации, Pluton, мантийные плюмы, плюм-литосферное взаимодействие, петрология, Geochemistry, Geology, Алтай, горы, Mantle plume, герцинская складчатость, Plume, Intrusion, Geophysics, Lithosphere, Petrology, Восточный Казахстан, Protolith

Abstract

We present petrological, isotopic, and geochronological data on gabbro-picrite plutons from the Altai collisional system of Hercynides (eastern Kazakhstan). The geological, geochemical, and geochronological data suggest that these rocks are indicators of the activity of the Tarim plume. The gabbro and picrites formed in two stages (~293 and 280 Ma) in an acid-to-basic succession, explained by a model for the interaction of thermochemical plumes with the lithosphere. Early igneous activity, which gave rise to subalkalic gabbro plutons, reflects the first interaction between the ascending plume and the lithosphere, with low-melting sublithospheric protoliths. Further interaction was characterized by the sublithospheric spread of the plume head with intense heating of the lithospheric base and possible intrusion of deep melts, which resulted in the formation of Cu–Ni–PGE gabbro-picrite plutons in the Altai collisional system and Northwest China.

Published

2013