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МАЙСКОЕ МНОГОЭТАПНОЕ ПРОЖИЛКОВО-ВКРАПЛЕННОЕ ЗОЛОТО-СУЛЬФИДНОЕ МЕСТОРОЖДЕНИЕ (ЧУКОТКА, РОССИЯ): МИНЕРАЛОГИЯ, ФЛЮИДНЫЕ ВКЛЮЧЕНИЯ, СТАБИЛЬНЫЕ ИЗОТОПЫ (О И S), ИСТОРИЯ И УСЛОВИЯ ОБРАЗОВАНИЯстатья
Статья опубликована в журнале из списка RSCI Web of Science
Информация о цитировании статьи получена из
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Статья опубликована в журнале из перечня ВАК
Статья опубликована в журнале из списка Web of Science и/или Scopus
Дата последнего поиска статьи во внешних источниках: 22 августа 2019 г.
- Авторы: Бортников Н.С., Брызгалов И.А., Кривицкая Н.Н., Прокофьев В.Ю., Викентъева О.В.
- Журнал: Геология рудных месторождений
- Том: 46
- Номер: 6
- Год издания: 2004
- Издательство: ФГБУ "Издательство "Наука"
- Местоположение издательства: Москва
- Первая страница: 475
- Последняя страница: 509
- DOI: WOS:000225941800001
- Аннотация: A study of the sequence and stages of the mineral-forming processes, chemical compositions of sulfides, fluid inclusions, and sulfur isotopes in sulfides and oxygen isotopes in quartz of the Maiskoe deposit has been carried out. Three genetically different mineralization styles of various ages, which were formed in different geological and tectonic environments, have been superimposed at the Maiskoe deposit. Disseminated auriferous pyrite-arsenopyrite ores formed during the early gold-sulfide stage. Different mineral aggregates composing cassiterite-sulfide veins originated during the next rare metal stage. Quartz-stibnite veins formed during the final gold-stibnite stage. The following two types of fluid inclusions were found in quartz from different mineralization zones: (1) three-phase inclusions containing liquid, a vapor bubble (with liquid CO2), and solid (halite, rarely two or three soluble phases); (2) three-phase inclusions containing liquid, a vapor bubble (without liquid CO2), and solid (halite); (3) three-phase H2O-rich inclusions with liquid CO2); (4) three-phase vapor-rich inclusions; and (5) two-phase inclusions containing liquid and a vapor bubble. Three fluids of different compositions and physicochemical parameters are assumed to have been involved in the ore-forming system of the deposit. A H2O + CO2 + CH4 fluid with a salt content of 8.2-2.2 wt % NaCl-equiv. deposited the economically valuable auriferous sulfide ores at 360-240degreesC and 1.1-0.9 kbars. A highly saline (37.5-30.0 wt % NaCl-equiv.) fluid and a low saline fluid formed the cassiterite-sulfide ores, which crystallized at a temperature of 500-170degreesC. The quartz-stibnite ores precipitated from an aqueous fluid with a salinity of 10.1-0.7 wt % NaCl-equiv. at 250-120degreesC. The delta(34)S values for arsenopyrite and pyrite from the auriferous orebodies range from -6.9 to -0.6 and -1.1 to -8.8parts per thousand, respectively. The delta(34)S values in sulfides from the cassiterite-sulfide mineralization are from -5.9 to -7.6parts per thousand for pyrite, -1.8 to +4.1parts per thousand for sphalerite, -0.4 to -7.9parts per thousand for galena, and -4.9 to -6.1parts per thousand for sulfosalt, minerals. The delta(34)S values for stibnite vary from -9.9 to +0.8parts per thousand. The delta(18)O values of quartz from auriferous zones are from +11.8 to +14.5parts per thousand, those of quartz from the veins formed during the cassiterite-sulfide megastage are from +1.7 to +4.1parts per thousand, and those of quartz from the quartz-stibnite veins are from +12.2 to +15.2parts per thousand. The ore formation conditions are assumed to have changed from mesoabyssal (the auriferous sulfide megastage) through shallow depth (the rare metal megastage) to subsurficial (the gold-stibnite megastage) environments. Fluids of magmatic origin and fluids originated at the heating of meteoric waters penetrated the hydrothermal thermal system. The role of the latter fluids increased toward later megastages of this hydrothermal system.
- Добавил в систему: Кривицкая Надежда Наумовна