Мақаланы E-mail арқылы жіберу Platinum-bearing Fe-Mn oceanic crust on basalts: mineralogy and model of formation
- Авторлар: Rudashevsky N.S.1, Rudashevsky V.N.1, Alikin О.V.1
-
Мекемелер:
- «CNT Instruments»
- Шығарылым: Том CLIII, № 2 (2024)
- Беттер: 32-55
- Бөлім: Articles
- URL: https://bakhtiniada.ru/0869-6055/article/view/263450
- DOI: https://doi.org/10.31857/S0869605524020028
- EDN: https://elibrary.ru/RNJCVU
- ID: 263450
Дәйексөз келтіру
Ашық рұқсат
Рұқсат берілді
Аннотация
Fe-Mn oceanic crust on basalts of the guyot in the Mid-Pacific Seamount (Pacific Ocean, depth 2486 m, chemical composition (wt %): Mn 24.2, Fe 12.6, Ni 0.59, Co 0.72, Cu 0.13; (ppm) Pt 0.35, Pd 0.0052), was studied using 3D-technology of mineralogical research. In addition to dominaiting vernadite and goethite, the following minerals are identified in the hydroseparation (HS) concentrates of the crust: 1) rock forming and accessory minerals of basalts (clinopyroxene, plagioclase, potassium feldspar, biotite, ilmenite, titanomagnetite, Ti-chrome spinel, zircon, apatite); 2) sulfides that are identical to those from the basalt substrate (pyrite, chalcopyrite, bornite, chalcocite, tennantite, nickel pentlandite Ni4S3, sphalerite, galena, argentite/acantite, molybdenite); 3) native metals (iron, nickel, copper, titanium, tungsten); 4) iron silicides (gupeiite Fe3Si, xifengite Fe5Si3, and hapkeite Fe5Si3); 5) platinum group minerals - unnamed (Cu,Pt)4Si and rustenburgite (Pt,Pd)3(Sn,Sb). The complexes of ore minerals in basalts are identical to those of the Fe-Mn crusts. Basalt accessories are assumed to be primary phases and a source of metals for the formation of native minerals. “Microdroplets” of native iron Fe, (Fe,Ni), nickel Ni, (Ni,Cr), (Ni,Fe) and copper Cu (sizes 20–100 microns, degree of sphericity up to 100%) represent the products of their crystallization from metal melts in basalts, transported by deep fluid into Fe-Mn crusts on these rocks. The zoned microglobules of 20–70 microns sizes with iron or native nickel (core) + successive rims of wüstite-magnetite and Fe-Mn hydroxides were identified. They were apparently formed during the movement of these solid microparticles (from bottom to the top) along intergranular spaces and other permeability channels in basalts under conditions of increasing oxygen fugacity and falling temperature at various levels of deep fluid infiltration. The crystallization of native metals in the Fe-Mn crust that are characterized by low-temperature (<10 °C) and oxidizing (fO2 MHG magnetite-hematite-goethite) conditions of mineral formation is impossible. The goethite replacement to different extent of many grains of relict Fe-minerals (sulfides and native metals) that are “foreign” to the Fe-Mn crust have been established. Fe-Mn crusts were formed as a result of the precipitation of colloidal particles Mn2+(Ba2+и Sr2+), to a lesser extent of the iron hydroxide Fe(ОН)3, as well as the concentration and transformation of micrograins of minerals of other metals, extracted by fluid from basaltic substrates. The comparison of the physico-chemical parameters of crystallization of basalts and native metals suggests another source of formation of native minerals in basalts, different from the postmagmatic basaltic fluid, i.e. deep-seated sharply reducing "hot" gas flows associated with superplumes. The mineralogical data determines a volcanogenic-fluid-oceanic model for the formation of Fe-Mn crusts on underwater oceanic elevations.
Толық мәтін
Авторлар туралы
N. Rudashevsky
«CNT Instruments»
Хат алмасуға жауапты Автор.
Email: vlad.rudashevsky@gmail.com
Ресей, Saint Petersburg
V. Rudashevsky
«CNT Instruments»
Email: vlad.rudashevsky@gmail.com
Ресей, Saint Petersburg
О. Alikin
«CNT Instruments»
Email: vlad.rudashevsky@gmail.com
Ресей, Saint Petersburg
Әдебиет тізімі
- Anand M., Taylor L.A., Nazarov M.A., Shu J., Mao H.K., Hemley R.J. Space weathering on airless planetary bodies: Clues from lunar mineral hapkeite. Proc. Nat. Acad. Sci. 2005. Vol. 101. P. 6847–6851.
- Andreev S.I. Metallogeny of ferromanganese formations in the Pacific Ocean. Saint Petersburg: Nedra, 1994. 191 p. (in Russian).
- Arsamakov H.I., Krugliyakov V.V., Marukshin A.I. Native metals and intermetallic compounds in pelagic sediments of the Pacific Ocean. Lithology and minerals. 1988. N 4. Р. 122–126 (in Russian).
- Astakhova I.N. Authigenic formations in Late Cenozoic sediments of the marginal seas of Eastern Asia. Vladivostok: Dalnauka, 2007a. 244 p. (in Russian).
- Astakhova I.N. Iron-manganese formations of the Sea of Japan, their chemical compositions and genesis. Moscow: Nauka, 2007b. P. 121–130 (in Russian).
- Astakhova I.N. Noble, rare earth, and nonferrous metals in ferromanganese crusts of the Sea of Japan. Doklady Earth Sci. 2008. Vol. 422. N 4. P. 1161–1166.
- Astakhova N.V. Precious and nonferrous metals in the ferromanganese crusts of the central Sea of Okhotsk. Oceanology. 2009. Vol. 49. N 3. P. 405–417.
- Astakhova N.V. Occurrence forms and distribution of precious and base metals in ferromanganese crusts from the Sea of Japan. Marine Geology. 2013. Vol. 53. N 6. P. 686–701.
- Astakhova N.V., Vedenskaya I.A. Chemical composition and genesis of iron-manganese formations of underwater volcanoes and seamounts in the Sea of Japan. Volcan. Seismol. 2003. N 6. P. 1–8 (in Russian).
- Astakhova N.V., Kolesnik O.N. Accessory metals in ferromanganese crusts of the Galagana ridge (Sea of Japan). Pacific Geology. 2011. Vol. 30. N 6. P. 97–109 (in Russian).
- Astakhova N.V., Kolesnik O.N., Syedin V.T. Ore mineralization in volcanic rocks from the submarine rises of the Sea of Japan. Geochem. Int. 2014. Vol. 52. N 2. P. 144–161.
- Astakhova N.V., Lelikov E.P. Features of the iron-manganese ore formation of the underwater Vityaz ridge. Geology and Geophysics. 2013. V. 54. N 5. P. 676–686 (in Russian).
- Astakhova N.V., Lelikov E.P. The specifics of ferromanganese ore formation on the submarine Vityaz’ Ridge (Pacific slope of the Kuril island arc). Russian Geol. Geophys. 2013. Vol. 54. N 5. P 518–525 (676–686).
- Astakhova N.V., Kolesnik О.N., Syedin V.Т. Non-ferrous, noble and rare earth metals in ferromanganese crusts and basalts of Belyavsky Seamount (Sea of Japan). Bull. KRASEC. Earth Sci. Ser. 2010. Vol. 16. N 2. P. 152–166 (in Russian).
- Bannich О.А., Budberg P.B., Alisova S.P. et al. State diagrams of binary and multicomponent iron-based systems. Moscow: Metallurgy, 1986. 440 p. (in Russian).
- Baturin G.N. Ocean ores. Moscow: Nauka, 1993. 301 p. (in Russian).
- Bortnikov N.S., Mochalov A.G., Cherkashev G.A. Native minerals and intermetallic compounds of noble and non-ferrous metals in sediments of the Markov Basin, Mid-Atlantic Ridge. Proc. Russian Acad. Sci. 2006. Vol. 409. N 4. P. 522–527 (in Russian).
- Cabri L.J., McDonald A.M., Stanley C.J., Rudashevsky N.S., Poirier G., Wilhelmij H.R., Zue W., Rudashevsky V.N. Palladosilicide, Pd2Si, a new mineral from the Kapalagulu intrusion, western Tanzania and the Bushveld Complex, South Africa. Miner. Mag. 2015. Vol. 79. N 2. P. 295–307.
- Davidov М.P., Sudarikov S.М., Kolosov О.V. Native metals and intermetallic compounds in sediments and suspensions of hydrothermally active segments of the East Pacific Rise. Lithology and minerals. 1998. N 1. P. 17–29 (in Russian).
- Frost B.R. Magnetic petrology: factors that control the occurrence of magnetite in crustal rocks. In: Oxide Minerals: Petrologic and Magnetic Significance. Ed. by D.H. Lindsley. Reviews in Mineralogy. 1991. Vol. 25. P. 129–219.
- Glavatskich S.F., Trubkin N.V. First findings of native tungsten and silver in the exhalation products of the large fissure eruption of Tolbachik volcano (Kamchatka). Doklady Earth Sci. 2000. Vol. 373. N 4. P. 523–526 (in Russian).
- Gramenitsky E.N., Kotelnikov А.R., Batanova А.М., Shekina Т.I., Plechov P.Yu. Experimental and technical petrology. Moscow: Nauchny Mir, 2000. 416 p. (in Russian).
- Halbach P., Scherhag C., Hebisch V., Marchig V. Geochemical and mineralogical control of different genetic types of deep-sea nodules from the Pacific Ocean. Miner. Deposita. 1981. Vol. 16. P. 59–84.
- Karpov G.А., Anikin L.P., Nikolayeva А.G. Native metals and intermetallic compounds in the ashes of active volcanoes in Kamchatka and Iceland. In: Proc. Conf. dedicated to Volcanologist Day “Volcanism and related processes” IVS FEB RAS. Petropavlovsk-Kamchatsky, 2012 (in Russian).
- Kolesnik O.N., Astakhova N.V. Grains of nonferrous and noble metals in iron–manganese formations and igneous rocks of submarine elevations of the Sea of Japan. Marine Geol. 2018. Vol. 58. N 1. P. 71–78 (in Russian).
- Konopleva E.V., Baturin G.N., Goleva R.V., Dubinchuk V.Т., Melnikov М.Е., Oshogina Е.G., Yubko V.М. Forms of gold and platinum in ferromanganese crusts of the Magellan Mountains (Pacific Ocean). Doklady Earth Sci. 2004. Vol. 397. N 2. P. 253–257 (in Russian).
- Lukin А.Е. Native-metallic micro- and nanoinclusions in the formations of oil and gas bearing basins-tracers of superdeep fluids. Geophysical Journal. 2009. Vol. 31. N 2. P. 61–92 (in Russian).
- Mizell K., Hein J.R., Au M., Gartman A. Estimates of metals contained in abyssal manganese nodules and ferromanganese crusts in the global ocean based on regional variations and genetic types of nodules Ed. by Sharma R. In: Perspectives on Deep-Sea Mining: Sustainability, Technology, Environmental Policy and Management. Springer International Publishing, Cham, 2022. P. 53–80.
- Novikov V.G. Ferromanganese sediments in the ocean: from nanoparticles to macro-objects. Priroda. 2019. N 11. P. 39–49 (in Russian).
- Oberthur T., Goldmann S. The Mooihoek platinum pipe, Eastern Bushveld Complex, South Africa – geochemistry and mineralization. Canad. J. Mine. 2023. Vol. 61. Р. 507–535.
- Oberthur T., Melcher F., Goldmann S., Frohlich F. High grade ores of the Onverwacht рlatinum рipe, Eastern Bushveld, South Africa. Canad. Miner. 2021. Vol. 59. P. 1397–1435.
- Phase diagrams of binary metal systems. Ed. by N.P. Lyakishev. Moscow: Mechanical Engineering, 1996-2000, 2001. Vol. 3. Book 1. 972 p. (in Russian).
- Richagov S.N., Glavatskih S.F., Sandimirova Е.I., Belousov V.I. Ore minerals in the structure of hydrothermal-magmatic systems: composition, distribution, conditions of formation. Geothermal and mineral resources of areas of modern volcanism. In: Proc. Int. Kuril-Kamchatka field seminar. Petropavlovsk-Kamchatsky, 2005. P. 363–379 (in Russian).
- Rudashevsky N.S., Kretser Yu.L., Anikeeva L.I., Andreev S.I., Torokhov M.P., Kazakhova V.Е. Platinum minerals in ferromanganese oceanic crusts. Doklady Earth Sci. 2001. Vol. 378. N 2. P. 246–250 (in Russian).
- Rudashevsky N.S., Loupal S.D., Rudashevsky V.N. Hydraulic classifier. Patent N 216530. Russian Federation. Moscow, 2001.
- Rudashevsky N.S., Rudashevsky V.N. Hydraulic classifier. Patent N 2281808. Russian Federation. Moscow, 2006.
- Rudashevsky N.S., Rudashevsky V.N. Hydraulic classifier. Patent N 69418. Russian Federation. Moscow, 2007.
- Rudashevsky N.S., Rudashevsky V.N. 3D-Mineralogical technology for studying of ores and technological products of primary deposits of precious metals. In: Proc. Anniversary Congress of the Russian Mineralogical Society “200 years of the RMS”. Saint Petersburg, 2017. Vol. 2. P. 146–148 (in Russian).
- Rudashevsky N.S., Rudashevsky V.N., Lupal S.D. “Method for separating granular materials and device for carrying out said method”. Patent Cooperation Treaty PCT/RU01/00123, Moscow, 20 April 2001, 10 May 2001. (Russian and English text).
- Rudashevsky N.S., Garuti G., Andersen J.C.O., Kretser Y.L., Rudashevsky V.N., Zaccarini F. Separation of accessory minerals from rocks and ores by hydroseparation (HS) technology: method and application to CHR-2 chromitite, Niquelandia, Brazil. Trans. Inst. Min. Metall. Section B, Appl. Earth. Sci. 2002. Vol. 111. P. B87–B94.
- Ryabchikov I.D., Kogarko L.N. Physicochemical parameters of the deep mantle plumes. Russian Geol. Geophys. 2016. Vol. 57. N 5. P. 874–888 (in Russian).
- Savelyev D.P., Filosofova Т.М. Mineralogical features of Cretaceous alkaline basalts of the Kamchatsky Mys Peninsula (Eastern Kamchatka). Bull. KRASEC. Earth Sci. Ser. 2005. N 5. P. 152–166 (in Russian).
- Savelyev D.P., Khanchuk А.I., Savelyeva О.L., Moskaleva S.V., Mikhailik P.E. First find of platinum in cosmogenic spherules of ferromanganese crusts (Fedorov Guyot, Magellan Seamounts, Pacific Ocean). Doklady Earth Sci. 2020. Vol. 491. N 2. P. 199–203.
- Saltikovsky А.Ya., Titayeva N.А., Genshaft Yu.S. Isotopy, geochemistry of Icelandic basalts and mantle plume. Volcanol. Seismol. 1998. N 3. P. 25–38 (in Russian).
- Shevko V.M., Serzhanov G.M., Badikova A.D., Uteуeva R.A. Thermal behavior of iron silicides. Int. J. Applied Fundamental Res. 2014. Part. 3. N 10. P. 41–45 (in Russian).
- Torokhov М.P., Melnikov М.Е. Accessory minerals in hydrogenous ferromanganese crusts of the Pacific Ocean: Placer accumulation mechanism. Doklady Earth Sci. 2005. Vol. 405. N 9. P. 1288–1290.
- Hansen М., Anderko К. Constitution of binary alloys. McGraw-Hill, New York, 1958. 989 p.
- Shunk F.A. Constitution of Binary Alloys: Second Supplement (McGraw-Hill Series in Materials Science and Engineering). McGraw-Hill Companies, 1969.
- Shterenberg L.Е., Vasilyeva G.L. Native metals and intermetallic compounds in sediments of the northeastern Pacific Ocean. Lithology and minerals. 1979. N 2. P. 133–139 (in Russian).
- Shterenberg L.Е., Aleksandrova V.А., Gablina I.F. et al. Composition and structure of manganese crusts of the Sea of Japan. Pacific Geology. 1986. N 1. P. 125–128 (in Russian).
- Usui A., Nishimura A. Submersible observations of hydrothermal manganese deposits on the Kaikata Seamount, Isu-Ogasawara (Bonin) Arc. Marine Geol. 1992. Vol. 106. P. 203–216.
- Yutkin L.А. Electrohydraulic effect and its application in industry. Leningrad: Mechanical Engineering, 1986. 253 p. (in Russian).
- Yu Zuxiang. Two new minerals gupeiite and xifengite in cosmic dusts from Yanshan. Acta Petrogica Mineralogica et Analitica. 1984. N 3. P. 231–238.
Қосымша файлдар
Ескертпе
[1] 25 ноября 2023 г. после продолжительной болезни ушел из жизни наш коллега, доктор геол.- мин. наук Николай Семенович Рудашевский, в прошлом член редколлегии Записок РМО, член Комиссий РМО: по локальным методам исследований и по новым минералам и названиям минералов. Николай Семенович родился 24 июня 1944 г. в селе Костенеево Елабужского р-на Татарской АССР, в находящейся в эвакуации семье профессора биологического факультета ЛГУ Семена Евгеньевича Рудашевского. Окончив школу с золотой медалью, поступил в Ленинградский университет, участвовал в экспедициях на Камчатку, Кольский полуостров, в Республику Тыва, Карелию и с отличием окончил кафедру минералогии в 1965 г. В 1972 г. защитил кандидатскую диссертацию в Ленинградском горном институте, а в 1989 г. – докторскую диссертацию «Платиноиды в породах ультрамафитовых формаций (минералогия и генезис)» во ВСЕГЕИ. В разные годы работал в Институте «Гипроникель» (1965–1978), Севзапгеологии (1978–1984), ВСЕГЕИ (1984–1990), ОАО «Механобр-Аналит» (1990–2000), Радиевом институте им. В.Г. Хлопина (2001–2016). Опубликовал более 300 работ в российских и зарубежных журналах, был первым автором и соавтором открытия 34 новых минералов, 21 из которых – минералы платиновой группы, соавтор 3-х патентов РФ на изобретения и 2-х монографий.
В последние два десятилетия Николай Семенович разработал, запатентовал и внедрил «3D-технологию минералого-геохимических исследований пород руд и техногенных продуктов», объединяющую метод электроимпульсной дезинтеграции (ЭИД) и новый способ гидросепарации с запатентованным оборудованием (Гидросепараторы HS-02 и HS-11) для гравитационного разделения измельченных материалов. В 2001 г. он вместе с сыном Владимиром основал сервисно-консалтинговую компанию «РС+» с лабораторией исследования состава минералов (с приборными комплексами оптического и локального электронно-микрозондового анализа, специальной пробоподготовки и гидросепарации). Компанией были опубликованы материалы по Ag-Au-Pd-Pt рудам Бушвельдского комплекса, ЮАР; Ag-Au-Pt-Pd минерализации карбонатитов Ковдорского массива, Кольский п-ов и месторождения Люлекоп, Палаборский массив, ЮАР; Au-рудам Березовского месторождения, Урал; Au-Ag-рудам месторождения Веладеро, Аргентина и др. Сегодня более 150 лабораторий в 20 странах используют гидросепараторы Рудашевского. Один из столпов в методологии исследования руд благородных металлов Луис Кабри (Канада) в своей статье сравнил влияние изобретения Н.С. Рудашевского на прогресс в открытии новых минералов благородных металлов с появлением электронно-зондового метода в 1959 г. Совместно с коллегами из различных университетов и научных организаций – Луисом Кабри (Канада), Томасом Обертюром (Германия), Йенсом Андерсеном, Энди МакДональдом (Англия), Оскаром Талхаммером (Австрия), Полом Вайблоном, Берни Сайни-Эйдукатом (США), Федерикой Заккарини и Джорджио Гарутти (Италия) и многими другими эта технология была апробирована на различных геологических объектах. Результаты исследования Н.С. Рудашевского легли в основу предложенных им теории флюидной дифференциации руд элементов платиновой группы и эволюции ультрамафитов в верхней мантии, флюидно-магматической модели формирования расслоенных интрузий, вулканогенно-флюидно-океанической модели формирования железо-марганцевых конкреций на базальтах в крупных бассейнах Земли. В результате использованной им 3D-технологии была разработана новая схема переработки хвостов и бедных забалансовых руд Березовского месторождения, внедренная на руднике, предложена схема переработки золотосодержащих хвостов Карабашского ГОКа.
Имя Николая Семеновича Рудашевского, талантливого и преданного своему делу ученого-исследователя будет жить в его научных трудах и минерале рудашевските (Fe,Zn)S, названном именем ученого. Примечание редколлегии.