Origin of potassium-bearing tourmalines of the Kumdy-Kolsky deposit (Kokchetav massif, Northern Kazakhstan): Study of Mineral inclusions

A. V. Korsakov; Корсаков А. В.; K. A. Musiyachenko; Мусияченко К. А.; D. S. Mikhailenko; Михайленко Д. С.; S. P. Demin; Демин С. П.

doi:10.24930/1681-9004-2023-23-4-500-514

Origin of potassium-bearing tourmalines of the Kumdy-Kolsky deposit (Kokchetav massif, Northern Kazakhstan): Study of Mineral inclusions

Autores: Korsakov A.V.¹, Musiyachenko K.A.¹^,2, Mikhailenko D.S.¹, Demin S.P.¹
Afiliações:
1. V.S. Sobolev Institute of Geology and Mineralogy, SB RAS
2. Department of Earth, Ocean and Atmospheric Sciences, University of British Columbia
Edição: Volume 23, Nº 4 (2023)
Páginas: 500-514
Seção: Articles
URL: https://journal-vniispk.ru/1681-9004/article/view/311137
DOI: https://doi.org/10.24930/1681-9004-2023-23-4-500-514
ID: 311137

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Resumo

Research subject. Mineral inclusions in potassium-bearing tourmaline crystals of the Kumdy-Kol microdiamond deposit. Aim. To reconstruct PT conditions for the origin of potassium-bearing tourmalines. Materials and methods. Mineral analysis and element mapping were performed using an X-ray spectral microanalyzer. Raman spectroscopy was used to detect the C and SiO2 polymorphs. Results. For the first time, diamond inclusions were identified in tourmalines with the potassium content ranging from 1.0 to 1.6 wt %. In addition, diamond-bearing zircon was detected in tourmaline crystals, with the K2O content below the detection limit. Previously, diamond inclusions had been exclusively identified only within the most potassium-rich cores of tourmaline crystals, which were approved as a new end member referred to as maruyamaite. Similar to the previous studies, the Kfs inclusions were recognized in both marumaite crystals and tourmaline crystals, with a variable content of potassium. Conclusions. The obtained findings indicate that high-pressure conditions may not be necessary for the formation of potassium-rich tourmaline. The chemical composition of the fluid is most likely to be the main factor controlling the appearance of tourmalines with an unusual composition.

Palavras-chave

maruyamaite, diamond, quartz, graphite, tourmaline, high pressure metamorphism, Kokchetav

Bibliografia

Добрецов Н.Л., Буслов М.М., Жимулев Ф.И., Травин А.В., Заячковский А.А. (2006) Венд-раннеордовикская геодинамическая эволюция и модель эксгумации пород сверхвысоких и высоких давлений Кокчетавской субдукционно-коллизионной зоны. Геология и геофизика, 47(4), 428-444.
Жимулев Ф.И., Полтаранина М.А., Корсаков А.В., Буслов М.М., Друзяка Н.В., Травин А.В. (2010) Структурное положение и петрология эклогитов позднекембрийско-раннеордовикской северо-кокчетавской тектонической зоны (Северный Казахстан). Геология и геофизика, 51(2), 240-256.
Корсаков А.В., Михайленко Д.С., Чжан Л., Шу Ю. (2023a) Включения кристаллов алмаза в турмалине шерл-увитового ряда: проблемы генезиса. Зап. Горного ин-та, 261, 1-9. https://doi.org/10.31897/PMI.2023.18
Корсаков А.В., Травин А.В., Юдин Д.С., Маршал Х.Р. (2009) Турмалин как 40Ar/39Ar геохронометр на примере метаморфических пород Кокчетавского массива (Казахстан). Докл. РАН, 424, 531-533.
Корсаков А.В., Шацкий В.С., Соболев Н.В. (1998) Первая находка коэсита в эклогитах Кокчетавского массива. Докл. РАН, 360, 77-81.
Корсаков А.В., Юдин Д.С., Мусияченко К.А., Демин С.П. (2023б) 40Ar/39Ar датирование маруямаита (калийсодержащего турмалина) из алмазоносных пород Кокчетавского массива. Геодинамика и тектонофизика, 14(3). https://doi.org/10.5800/GT-2023-14-3-0699
Лаврентьев Ю.Г., Карманов Н.С., Усова Л.В. (2015) Электронно-зондовое определение состава минералов: микроанализатор или сканирующий электронный микроскоп? Геология и геофизика, 56(8), 1473-1482.
Лаврова Л.Д., Печников В.А., Петрова М.А., Заячковский А.А. (1996) Геология Барчинской алмазоносной площади. Отеч. геология, (12), 20-27.
Лаврова Л.Д., Печников В.А., Плешаков А.М., Надеждина Е.Д., Шуколюков Ю.А. (1999) Новый генетический тип алмазных месторождений. М.: Научный мир, 221 с.
Летников Ф.А. (1983) Образование алмазов в глубинных тектонических зонах. Докл. АН СССР, 271, 433-435.
Мусияченко К.А., Корсаков А.В., Летников Ф.А. (2021) Новое проявление маруямаита. Докл. РАН, 498, 58-65.
Розен О.М., Зорин Ю.М., Заячковский А.А. (1972) Обнаружение алмаза в связи с эклогитами в докембрии Кокчетавского массива. Докл. АН СССР, 203, 674-676.
Сафонов О.Г. (2007) Модели эволюции глубинных щелочных жидкостей. Дис. ... канд. геол.-мин. наук. М., 403 с.
Соболев Н.В., Шацкий В.С. (1987) Включения минералов углерода в гранатах метаморфических пород. Геология и геофизика, 28(7), 77-80.
Соболев Н.В., Шацкий В.С., Вавилов М.А., Горяйнов С.В. (1991) Включение коэсита в цирконе алмазосодержащих гнейсов Кокчетавского массива - первая находка коэсита в метаморфических породах на территории СССР. Докл. АН СССР, 321, 184-188.
Соболев Н.В., Шацкий В.С., Вавилов М.А., Горяйнов С.В. (1994) Циркон высокобарических метаморфических пород складчатых областей как уникальный контейнер включений алмаза, коэсита и сосуществующих минералов. Докл. РАН, 334, 488-492.
Angel R.J., Mazzucchelli M.L., Alvaro M., Nimis P., Nestola F. (2014) Geobarometry from host-inclusion systems: The role of elastic relaxation. Amer. Miner., 99, 2146-2149.
Berryman E.J., Wunder B., Wirth R., Rhede D., Schettler G., Franz G., Heinrich W. (2015) An experimental study on K and Na incorporation in dravitic tourmaline and insight into the origin of diamondiferous tourmaline from the Kokchetav Massif, Kazakhstan. Contrib. Mineral. Petrol., 169, 28. https://doi.org/10.1007/s00410-015-1116-9
Berryman E., Wunder B., Rhede D. (2014) Synthesis of K-dominant tourmaline. Amer. Miner., 99, 539-542.
Borghini A., Ferrero S., O'Brien P.J., Laurent O., Gunter C., Ziemann M.A. (2020) Cryptic metasomatic agent measured in situ in Variscan mantle rocks: Melt inclusions in garnet of eclogite, Granulitgebirge, Germany. Metamorphic Geol., 38, 207-234.
Chopin C. (1984) Coesite and pure pyrope in high-grade blueschists of Western Alps: a first record and some consequences. Contrib. Mineral. Petrol., 86, 107-118.
Chopin C., Sobolev N.V. (1995) Principal mineralogic indicators of UHP in crustal rocks. ultrahigh Pressure Metamorphism. (Ed. by R.G. Coleman, X. Wang). Cambridge: Cambridge University Press, 96-131.
Dobretsov N.L., Sobolev N.V., Shatsky V.S., Coleman R.G., Ernst W.G. (1995) Geotectonic evolution of diamondi-ferous paragneisses of the Kokchetav complex, Northern Kazakhstan - the geologic enigma of ultrahigh-pressure crustal rocks within Phanerozoic foldbelt. Island Arc, 4, 267-279.
Dobrzhinetskaya L.F., Braun T.V., Sheshkel G.G., Podkuiko Y.A. (1994) Geology and structure of diamond-bearing rocks of the Kokchetav massif, Kazakhstan. Tectonophysics, 233, 293-313.
Ferrero S., Angel R.J. (2018) Micropetrology: Are Inclusions Grains of Truth? J. Petrol., 59, 1671-1700.
Ferrero S., Bartoli O., Cesare B., Salvioli-Mariani E., Acosta-Vigil A., Cavallo A., Groppo C., Battiston S. (2012) Microstructures of melt inclusions in anatectic metasedimentary rocks. J. Metamorphic Geol., 30, 303-322.
Ferrero S., Ziemann M.A., Angel R.J., O'Brien P.J., Wunder B. (2015) Kumdykolite, kokchetavite, and cristobalite crystallized in nanogranites from felsic granulites, Orlica-Snieznik Dome (Bohemian Massif): not evidence for ultrahigh-pressure conditions. Contrib. Mineral. Petrol., 171, 3.
Hermann J., Green D.H. (2001) Experimental constraints on high pressure melting in subducted crust. Earth Planet. Sci. Lett., 188, 149-186.
Hwang S.L., Yui T.F., Chu H.T., Shen P., Liou J.G., Sobolev N.V. (2013) Oriented kokchetavite compound rods in clinopyroxene of Kokchetav ultrahigh-pressure rocks. J. Asian Earth Sci., 63, 56-69.
Hwang S.-L., Shen P., Chu H.-T., Yui T.-F., Liou J.G., Sobolev N.V. (2009) Kumdykolite, an orthorhombic polymorph of albite, from the Kokchetav ultrahigh-pressure massif, Kazakhstan. Europ. J. Miner., 21, 1325-1334.
Hwang S.-L., Shen P., Chu H.-T., Yui T.-F., Liou J.G., Sobolev N.V., Shatsky V.S. (2005) Crust-derived potassic fluid in metamorphic microdiamond. Earth Planet. Sci. Lett., 231, 295-306.
Hwang S.-L., Shen P., Chu H.-T., Yui T.-F., Liou J.G., Sobolev N.V., Zhang R.-Y., Shatsky V.S., Zayachkovsky A.A. (2004) Kokchetavite: a new potassium-feldspar polymorph from the Kokchetav ultrahigh-pressure terrane. Contrib. Mineral. Petrol., 148, 380-389.
Kanzaki M., Xue X., Amalberti J., Zhang Q. (2012) Raman and NMR spectroscopic characterization of high-pressure K-cymrite (KAlSi3O8
Korsakov A.V., Hermann J. (2006) Silicate and carbonate melt inclusions associated with diamonds in deeply subducted carbonate rocks. Earth Planet. Sci. Lett., 241, 104-118.
Korsakov A.V., Rezvukhina O.V., Rezvukhin D.I., Greshnyakov E.D., Shur V.Y. (2020) Dumortierite and tourmaline from the Barchi-Kol diamond-bearing kyanite gneisses (Kokchetav massif): A Raman spectroscopic study and petrological implications. J. Raman Spectroscopy, 51, 1839-1848.
Korsakov A.V., Shatsky V.S., Sobolev N.V., Zayachkovsky A.A. (2002) Garnet-biotite-clinozoisite gneisses: a new type of diamondiferous metamorphic rocks of the Kokchetav massif. Europ. J. Miner., 14, 915-929.
Korsakov A.V., Theunissen K., Smirnova L.V. (2004) Inter-granular diamonds derived from partial melting of crustal rocks at ultrahigh-pressure metamorphic conditions. Terra Nova, 16, 146-151.
Korsakov A.V., Zhimulev E.I., Mikhailenko D.S., Demin S.P., Kozmenko O.A. (2015) Graphite pseudomorphs after diamonds: An experimental study of graphite morphology and the role of H2O in the graphitisation process. Lithos, 236-237, 16-26. https://doi.org/10.1016/j.lithos.2015.08.012
Lussier A., Ball N.A., Hawthorne F.C., Henry D.J., Shimizu R., Ogasawara Y., Ota T. (2016) Maruyamaite, K(MgAl2)(Al5Mg)Si6O18(BO33(OH)3O, a potassium-dominant tourmaline from the ultrahigh-pressure Kokchetav massif, northern Kazakhstan: Description and crystal structure. Amer. Miner., 101, 355-361.
Marschall H.R., Korsakov A.V., Luvizotto G.L., Nasdala L., Ludwig T. (2009) On the occurrence and boron isotopic composition of tourmaline in (ultra)high-pressure metamorphic rocks. J. Geol. Soc., london, 166, 811-823.
Massonne H.-J., Bernhardt H.-J., Dettmar D., Kessler E., Medenbach O., Westphal T. (1998) Simple identification and quantification of microdiamonds in rock thinsections. Europ. J. Miner., 10, 497-504.
Mikhno A.O., Korsakov A.V. (2013) K2O prograde zoning pattern in clinopyroxene from the Kokchetav diamond-grade metamorphic rocks: Missing part of metamorphic history and location of second critical end point for calcsilicate system. Gondwana Res., 23, 920-930.
Mikhno A.O., Schmidt U., Korsakov A.V. (2013) Origin of K-cymrite and kokchetavite in the polyphase mineral inclusions from Kokchetav UHP calc-silicate rocks: evidence from confocal Raman imaging. Europ. J. Miner., 25, 807-816.
Musiyachenko K.A., Korsakov A.V., Shimizu R., Zelenovskiy P.S., Shur V.Y. (2020). New insights on Raman spectrum of K-bearing tourmaline. J. Raman Spectroscopy, 51, 1415-1424.
Ogasawara Y., Fukasawa K., Maruyama S. (2002) Coesite exsolution from supersilicic titanite in UHP marble from the Kokchetav massif, northern Kazakhstan. Amer. Miner., 87, 454-461.
Ota T., Kobayashi K., Kunihiro T., Nakamura E. (2008) Boron cycling by subducted lithosphere; insights from diamondiferous tourmaline from the Kokchetav ultrahigh-pressure metamorphic belt. Geochim. Cosmochim. Acta, 72, 3531-3541.
Perchuk L.L., Safonov O.G., Yapaskurt V.O., Barton J.M.B. (2002) Crystal-melt equilibria involving potassium-bearing clinopyroxene as indicator of mantle-derived ultra-high-potassic liquids: an analytical review. Lithos, 60, 89-111.
Perchuk L.L., Yapaskurt V.O. (1998) Mantle-derived ultra-potassic liquids. Geol. Geophys., 39(12), 1756-1765.
Romanenko A.V., Rashchenko S.V., Sokol A.G., Korsakov A.V., Seryotkin Y.V., Glazyrin K.V., Musiyachenko K. (2021) Crystal structures of K-cymrite and kokchetavite from single-crystal X-ray diffraction. Amer. Miner., 106, 404-409.
Safonov O.G., Perchuk L.L., Litvin Y.A., Bindi L. (2005) Phase relations in the CaMgSi2O6-KAlSi3O8 join at 6 and 3.5 GPa as a model for formation of some potassium-bearing deep-seated mineral assemblages. Contrib. Mineral. Petrol., 149, 316-337.
Schulze D.J., Helmstaedt H. (1988) Coesite-Sanidine Eclogites from Kimberlite: Products of Mantle Fractionation or Subduction? J. Geol., 96, 435-443.
Seki Y., Kennedy G.C. (1964) The breakdown of potassium feldspar, KAlSi3O8 at high temperatures and high pressures. amer. Miner., 49, 1688-1706.
Shatsky V.S., Sobolev N.V., Vavilov M.A. (1995) Diamond-bearing metamorphic rocks of the Kokchetav massif (northern Kazakhstan). ultra-High Pressure Metamorphism. Cambridge: Cambridge University Press, 427-455.
Shimizu R., Ogasawara Y. (2005) K-Tourmaline in diamond-bearing rock from Kokchetav. Mitteilungen der Osterreichischen Mineralogischen Gesellschaft, 150.
Shimizu R., Ogasawara Y. (2013) Diversity of potassium-bearing tourmalines in diamondiferous Kokchetav UHP metamorphic rocks: A geochemical recorder from peak to retrograde metamorphic stages. J. Asian Earth Sci., 63, 39-55.
Smith D.C. (1984) Coesite in clinopyroxene in the Caledonides and its implications for geodynamics. Nature, 310, 641-644.
Smyth J.R., Hatton C.J. (1977) A coesite-sanidine grospydite from the Roberts Victor kimberlite. Earth Planet. Sci. lett., 34, 284-290.
Sobolev N.V., Shatsky V.S. (1990) Diamond inclusions in garnets from metamorphic rocks: a new environment for diamond formation. Nature, 343, 742-746.
Theunissen K., Dobretsov N.L., Korsakov A., Travin A., Shatsky V.S., Smirnova L., Boven A. (2000) Two contrasting petrotectonic domains in the Kokchetav mega-melange (north Kazakhstan): difference in exhumation mechanisms of ultrahigh-pressure crustal rocks, or a result of subsequent deformation? Island Arc, 9, 284-303.
Zedgenizov D.A., Kagi H., Shatsky V.S., Ragozin A.L. (2014) Local variations of carbon isotope composition in diamonds from Sao-Luis (Brazil): Evidence for heterogenous carbon reservoir in sublithospheric mantle. Chem. Geol., 363, 114-124.

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Volume 25, Nº 3 (2025)

Origin of potassium-bearing tourmalines of the Kumdy-Kolsky deposit (Kokchetav massif, Northern Kazakhstan): Study of Mineral inclusions

Texto integral

Resumo

Palavras-chave

Sobre autores

A. Korsakov

K. Musiyachenko

D. Mikhailenko

S. Demin

Bibliografia

Arquivos suplementares