Continuous Be mineralization from two-mica granite to pegmatite: Critical element enrichment processes in a Himalayan leucogranite pluton

Chen Liu; Ru-Cheng Wang; Robert L. Linnen; Fu-Yuan Wu; Lei Xie; Xiao-Chi Liu

doi:10.2138/am-2022-8353

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Continuous Be mineralization from two-mica granite to pegmatite: Critical element enrichment processes in a Himalayan leucogranite pluton

Chen Liu , Ru-Cheng Wang , Robert L. Linnen , Fu-Yuan Wu , Lei Xie und Xiao-Chi Liu

Veröffentlicht/Copyright: 3. Januar 2023

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Abstract

Beryllium is a critical metal typically concentrated in highly fractionated granitic rocks such as the leucogranites in the Himalaya. Here, we report beryl mineralization that was continuous from the earlier and less-evolved two-mica granite to the highly evolved albite granite and pegmatite in a typical leucogranite pluton at Pusila in the central of Himalaya. Textural and mineral chemical evidence support a magmatic origin for beryl, and the trends of beryl crystal chemistry indicate magma differentiation. Despite low to moderate fractionation of the biotite granite and two-mica granite in the Pusila leucogranite pluton, the Be contents (~7 μg/g, beryl-free and ~22 μg/g, beryl-bearing, respectively) of these granites are much higher than the average for biotite- and two-mica granites worldwide (~3–4 and 5–10 μg/g, respectively), indicating that the initial magma had a relatively high-Be concentration. The gneisses of Greater Himalayan System, considered the protolith, also show a higher Be abundance (~4–6 μg/g) than the mean value of pelitic rocks worldwide (~2–3 μg/g), which could be the source reservoir of Be. The source contributed the initial Be to the melt, and fractionation resulted in the onset of beryl crystallization from the interstitial residual melt in the two-mica granite. The ubiquity of beryl in two-mica granite to pegmatite stages of the Pusila pluton is explained by a continuous crystallization model, although there was a delay in the onset of beryl crystallization in the two-mica granite. Modeling based on Rayleigh fractionation indicates that Be becomes compatible once saturation is attained because of the beryl crystallization. Our findings indicate that the enrichment of critical elements (e.g., Be) is controlled not only by fractional crystallization but also by the buffering action of a saturating phase (e.g., beryl) on the concentration of the critical element in the melt.

Keywords: Himalayan leucogranite; beryllium; beryl; source; fractionation; delayed crystallization; Lithium, beryllium and boron: Quintessentially crustal

† Special collection papers can be found online at http://www.minsocam.org/MSA/AmMin/special-collections.html.

Funding statement: This study was supported by the National Natural Science Foundation of China (Grant No. 91855209), Second Comprehensive Scientific Investigation into Qinghai-Tibet Plateau (Grant No. 2019QZKK0802), the scholarship from China Scholarship Council (File No. 201906190151) to C.L., and the Fundamental Research Funds for the Central Universities (DLTD2014).

Acknowledgments

We sincerely thank Wen-Lan Zhang, Huan Hu, and Juan Li from State Key Laboratory for Mineral Deposits Research for their technical assistance with EMPA, LA-ICPMS, and SEM analyses. We sincerely thank the two reviewers, Gerhard Franz, and Milan Novák, for their constructive comments. We also particularly thank the Associate Editor Edward S. Grew for bringing his considerable expertise with patience to bear on important details.

References cited

Acosta-Vigil, A., London, D., Morgan, G.B. VI, and Dewers, T.A. (2003) Solubility of excess alumina in hydrous granitic melts in equilibrium with peraluminous minerals at 700–800 °C and 200 MPa, and applications of the aluminum saturation index. Contributions to Mineralogy and Petrology, 146, 100–119.Suche in Google Scholar

Aikman, A.B., Harrison, T.M., and Hermann, J. (2012) The origin of Eo- and Neo-Himalayan granitoids, Eastern Tibet. Journal of Asian Earth Sciences, 58, 143–157.Suche in Google Scholar

Aurisicchio, C., Fioravanti, G., Grubessi, O., and Zanazzi, P.F. (1988) Reappraisal of the crystal chemistry of beryl. American Mineralogist, 73, 826–837.Suche in Google Scholar

Ayres, M., Harris, N., and Vance, D. (1997) Possible constraints on anatectic melt residence times from accessory mineral dissolution rates: an example from Himalayan leucogranites. Mineralogical Magazine, 61, 29–36.Suche in Google Scholar

Bartels, A., Behrens, H., Holtz, F., and Schmidt, B. (2015) The effect of lithium on the viscosity of pegmatite forming liquids. Chemical Geology, 410, 1–11.Suche in Google Scholar

Bea, F., Pereira, M.D., Corretgé, L.G., and Fershtater, G.B. (1994) Differentiation of strongly peraluminous, perphosphorus granites: The pedrobernardo pluton, central Spain. Geochimica et Cosmochimica Acta, 58, 2609–2627.Suche in Google Scholar

Beus, A.A. (1966) Geochemistry of Beryllium and Genetic Types of Beryllium Deposits, 401 p. Freeman.Suche in Google Scholar

Bosi, F., Naitza, S., Skogby, H., Secchi, F., Conte, A.M., Cuccuru, S., Hålenius, U., De La Rosa, N., Kristiansson, P., Charlotta Nilsson, E.J., Ros, L., and Andreozzi, G.B. (2018) Late magmatic controls on the origin of schorlitic and foititic tourmalines from late-Variscan peraluminous granites of the Arbus plu-ton (SW Sardinia, Italy): Crystal-chemical study and petrological constraints. Lithos, 308-309, 395–411.Suche in Google Scholar

Breaks, F.W., and Moore, J.M. (1992) The Ghost Lake Batholith, Superior Province of northwestern Ontario: A fertile, S-type, peraluminous granite—rare-element pegmatite system. The Canadian Mineralogist, 30, 835–875.Suche in Google Scholar

Breaks, F.W., and Tindle, A.G. (2001) Rare-element mineralization of the Separation Lake area, northwest Ontario: Characteristics of a new discovery of complex-type, petalite-subtype, Li-Rb-Cs-Ta pegmatite. Industrial Minerals in Canada, 53, 159–178.Suche in Google Scholar

Breiter, K., Sokolová, M., and Sokol, A. (1991) Geochemical specialization of the tin-bearing granitoid massifs of NW Bohemia. Mineralium Deposita, 26, 298–306.Suche in Google Scholar

Breiter, K., Frýda, J., Seltmann, R., and Thomas, R. (1997) Mineralogical Evidence for two magmatic stages in the evolution of an extremely fractionated P-rich rare-metal granite: The Podlesí Stock, Krušné Hory, Czech Republic. Journal of Petrology, 38, 1723–1739.Suche in Google Scholar

Buriánek, D., and Novák, M. (2004) Morphological and compositional evolution of tourmaline from nodular granite at Lavičky near Velké Meziříčí, Moldanu-bicum, Czech Republic. Journal of the Czech Geological Society, 49, 81–90.Suche in Google Scholar

Černý, P. (2002) Mineralogy of beryllium in granitic pegmatites. Reviews in Mineralogy and Geochemistry, 50, 405–444.Suche in Google Scholar

Černý, P., and Ercit, T.S. (2005) The classification of granitic pegmatites revisited. Canadian Mineralogist, 43, 2005–2026.Suche in Google Scholar

Chakhmouradian, A.R., Smith, M.P., and Kynicky, J. (2015) From “strategic” tungsten to “green” neodymium: A century of critical metals at a glance. Ore Geology Reviews, 64, 455–458.Suche in Google Scholar

Charoy, B. (1999) Beryllium speciation in evolved granitic magmas: phosphates versus silicates. European Journal of Mineralogy, 11, 135–148.Suche in Google Scholar

Chen, G.H., Shu, L.S., Shu, L.M., Zhang, C., and Ou-Yang, Y.P. (2016) Geological characteristics and mineralization setting of the Zhuxi tungsten (copper) polymetallic deposit in the Eastern Jiangnan Orogen. Science China Earth Sciences, 59, 803–823.Suche in Google Scholar

Chen, W., Chen, B., and Sun, K.K. (2018) Petrogenesis of the Zengjialong highly differentiated granite in the Pengshan Sn-polymetallic ore field, Jiangxi Province. Geochimica, 47, 554–574 (in Chinese with English abstract).Suche in Google Scholar

Drake, M.J., and Weill, D.F. (1975) Partition of Sr, Ba, Ca, Y, Eu²⁺, Eu³⁺, and other REE between plagioclase feldspar and magmatic liquid: an experimental study. Geochimica et Cosmochimica Acta, 39, 689–712.Suche in Google Scholar

Ertl, A., Kolitsch, U., Dyar, M.D., Meyer, H.P., Rossman, G.R., Henry, D.J., Prem, M., Ludwig, T., Nasdala, L., Lengauer, C.L., Tillmanns, E., and Niedermayr, G. (2016) Fluor-schorl, a new member of the tourmaline supergroup, and new data on schorl from the cotype localities. European Journal of Mineralogy, 28, 163–177.Suche in Google Scholar

Evensen, J.M., and London, D. (2002) Experimental silicate mineral/melt partition coefficients for beryllium and the crustal Be cycle from migmatite to pegmatite. Geochimica et Cosmochimica Acta, 66, 2239–2265.Suche in Google Scholar

Evensen, J.M., London, D., and Wendlandt, R.F. (1999) Solubility and stability of beryl in granitic melts. American Mineralogist, 84, 733–745.Suche in Google Scholar

Foley, N.K., Jaskula, B.W., Piatak, N.M., and Schulte, R.F. (2017) Beryllium. In K.J. Schulz, J.H. DeYoung, R.R. Seal, and D.C. Bradley, Eds., Critical Mineral Resources of the United States: Economic and Environmental Geology and Prospects for Future Supply. U.S. Geological Survey. https://doi.org/10.3133/pp1802E.Suche in Google Scholar

Grew, E.S. (2002) Beryllium in metamorphic environments (emphasis on aluminous compositions). Reviews in Mineralogy and Geochemistry, 50, 487–549.Suche in Google Scholar

Grew, E.S., and Hazen, R.M. (2014) Beryllium mineral evolution. American Mineralogist, 99, 999–1021.Suche in Google Scholar

Grew, E.S., Yates, M.G., Shearer, C.K., Hagerty, J.J., Sheraton, J.W., and Sandiford, M. (2006) Beryllium and other trace elements in paragneisses and anatectic veins of the ultrahigh-temperature Napier Complex, Enderby Land, east Antarctica: The role of sapphirine. Journal of Petrology, 47, 859–882.Suche in Google Scholar

Harris, N., and Inger, S. (1992) Trace element modelling of pelite-derived granites. Contributions to Mineralogy and Petrology, 110, 46–56.Suche in Google Scholar

Harris, N., Vance, D., and Ayres, M. (2000) From sediment to granite: Timescales of anatexis in the upper crust. Chemical Geology, 162, 155–167.Suche in Google Scholar

Hopkinson, T., Harris, N., Roberts, N.M.W., Warren, C.J., Hammond, S., Spencer, C.J., and Parrish, R.R. (2020) Evolution of the melt source during protracted crustal anatexis: An example from the Bhutan Himalaya. Geology, 48, 87–91.Suche in Google Scholar

Hörmann, P.K. (1978) Beryllium. In K.H. Wedepohl, Ed., Handbook of Geochemistry II/1, p. 1–6. Springer.Suche in Google Scholar

Icenhower, J., and London, D. (1995) An experimental study of element partitioning among biotite, muscovite, and coexisting peraluminous silicic melt at 200 MPa (H²O). American Mineralogist, 80, 1229–1251.Suche in Google Scholar

Icenhower, J., and London, D. (1996) Experimental partitioning of Rb, Cs, Sr, and Ba between alkali feldspar and peraluminous melt. American Mineralogist, 81, 719–734.Suche in Google Scholar

Le Fort, P., Cuney, M., Deniel, C., France-Lanord, C., Sheppard, S.M.F., Upreti, B.N., and Vidal, P. (1987) Crustal generation of the Himalayan leucogranites. Tectonophysics, 134, 39–57.Suche in Google Scholar

Linnen, R.L., Lichtervelde, M.V., and Černý, P. (2012) Granitic pegmatites as sources of strategic metals. Elements, 8, 275–280.Suche in Google Scholar

Liu, Y.S., Hu, Z.C., Gao, S., Günther, D., Xu, J., Gao, C.G., and Chen, H.H. (2008) In situ analysis of major and trace elements of anhydrous minerals by LA-ICP-MS without applying an internal standard. Chemical Geology, 257, 34–43.Suche in Google Scholar

Liu, C., Wang, R.C., Wu, F.Y., Xie, L., Liu, X.C., Li, X.K., Yang, L., and Li, X.J. (2020) Spodumene pegmatites from the Pusila pluton in the higher Himalaya, South Tibet: Lithium mineralization in a highly fractionated leucogranite batholith. Lithos, 358-359, 105421.Suche in Google Scholar

London, D. (2008) Pegmatites. In R.F. Martin, Ed., Canadian Mineralogist, 347 p. Special Publication 10.Suche in Google Scholar

London, D. (2015) Reading pegmatites: Part 1—What beryl says. Rocks & Minerals, 90, 138–153.Suche in Google Scholar

London, D. (2019) Reading pegmatites: Part 5—What pollucite says. Rocks & Minerals, 94, 420–427.Suche in Google Scholar

London, D., and Evensen, J.M. (2002) Mineralogy of beryllium in granitic pegmatites. Reviews in Mineralogy and Geochemistry, 50, 445–486.Suche in Google Scholar

London, D., and Morgan, G.B. (2012) The pegmatite puzzle. Elements, 8, 263–268.Suche in Google Scholar

Long, P.E. (1978) Experimental determination of partition coefficients for Rb, Sr, and Ba between alkali feldspar and silicate liquid. Geochimica et Cosmochimica Acta, 42, 833–846.Suche in Google Scholar

Lowell, G.R., and Young, G.J. (1999) Interaction between coeval mafic and felsic melts in the St. Francois Terrane of Missouri, USA. Precambrian Research, 95, 69–88.Suche in Google Scholar

Montel, J.M. (1993) A model for monazite/melt equilibrium and application to the generation of granitic magmas. Chemical Geology, 110, 127–146.Suche in Google Scholar

Norton, J.J., and Redden, J.A. (1990) Relations of zoned pegmatites to other pegmatites, granite, and metamorphic rocks in the southern Black Hills, South Dakota. American Mineralogist, 75, 631–655.Suche in Google Scholar

Novák, M., Selway, J.B., and Houzar, S. (1998) Potassium-bearing, fluorine-rich tourmaline from metamorphosed fluorite layer in leucocratic orthogneiss at Nedvědice, Svratka Unit, western Moravia. Journal of the Czech Geological Society, 43, 37–44.Suche in Google Scholar

Patiño Douce, A.E., and Harris, N. (1998) Experimental constraints on Himalayan anatexis. Journal of Petrology, 39, 689–710.Suche in Google Scholar

Pollard, P.T. (2021) The Yichun Ta-Sn-Li Deposit, South China: Evidence for extreme chemical fractionation in F-Li-P-rich magma. Economic Geology, 116, 453–469.Suche in Google Scholar

Qi, L., Hu, J., and Gregoire, D.C. (2000) Determination of trace elements in granites by inductively coupled plasma mass spectrometry. Talanta, 51, 507–513.Suche in Google Scholar

Raimbault, L., Cuney, M., Azencott, C., Duthou, J.L., and Joron, J.L. (1995) Geochemical evidence for a multistage magmatic genesis of Ta-Sn-Li mineralization in the granite at Beauvoir, French Massif Central. Economic Geology, 90, 548–576.Suche in Google Scholar

Ramı́rez, J.A., and González-Menéndez, L.A. (1999) Geochemical study of two peraluminous granites from South-Central Iberia: The Nisa-Albuquerque and Jalama Batholiths. Mineralogical Magazine, 63, 85–104.Suche in Google Scholar

Ramı́rez, J.A., and Grundvig, S. (2000) Causes of geochemical diversity in peraluminous granitic plutons: the Jálama pluton, Central-Iberian Zone (Spain and Portugal). Lithos, 50, 171–190.Suche in Google Scholar

Rudnick, R., and Gao, S. (2014) Composition of the continental crust. In R.L. Rudnick, H.D. Holland, and K.K. Turekian, Eds., Treatise on Geochemistry, 3, p. 1–64. Elsevier.Suche in Google Scholar

Ryan, J.G. (2002) Trace-element systematics of beryllium in terrestrial materials. Reviews in Mineralogy and Geochemistry, 50, 121–145.Suche in Google Scholar

Sawyer, E. (1987) The role of partial melting and fractional crystallization in determining discordant migmatite leucosome compositions. Journal of Petrology, 28, 445–473.Suche in Google Scholar

Scaillet, B., France-Lanord, C., and Le Fort, P. (1990) Badrinath-Gangotri plutons (Garhwal, India): Petrological and geochemical evidence for fractionation processes in a high Himalayan leucogranite. Journal of Volcanology and Geothermal Research, 44, 163–188.Suche in Google Scholar

Sovacool, B.K., Ali, S.H., Bazilian, M., Radley, B., Nemery, B., Okatz, J., and Mulvaney, D. (2020) Sustainable minerals and metals for a low-carbon future. Science, 367, 30–33.Suche in Google Scholar

Taylor, S.R., and McLennan, S.M. (1985) The Continental Crust: Its Composition and Evolution, 312 p. Blackwell.Suche in Google Scholar

Thomas, R., and Davidson, P. (2013) The missing link between granites and granitic pegmatites. Journal of Geosciences, 58, 183–200.Suche in Google Scholar

Tian, E.N., Wang, R.C., Xie, L., Zhang, W.L., Che, X.D., and Zhang, R.Q. (2020) Mineralogy and geochemistry of the newly discovered Late Mesozoic granitepegmatite and associated Sn-Nb-Ta-Be mineralization in the Miao’ershan-Yuechengling composite batholith, northern Guangxi, South China. Journal of Asian Earth Sciences, 190, 104149.Suche in Google Scholar

Trueman, D.L., and Sabey, P. (2014) Beryllium. In G. Gunn, Ed., Critical Metals Handbook, p. 99–119. WileySuche in Google Scholar

von Goerne, G., Franz, G., and Wirth, R. (1999) Hydrothermal synthesis of large dravite crystals by the chamber method. European Journal of Mineralogy, 11, 1061–1078.Suche in Google Scholar

von Goerne, G., Franz, G., and van Hinsberg, V. (2011) Experimental determination of Na-Ca distribution between tourmaline and fluid in the system CaO-Na₂O-MgO-Al₂O₃-SiO₂-B₂O₃-H₂O. Canadian Mineralogist, 49, 137–152.Suche in Google Scholar

Wang, R.C., Wu, F.Y., Xie, L., Liu, X.C., Wang, J.M., Yang, L., Lai, W., and Liu, C. (2017) A preliminary study of rare-metal mineralization in the Himalayan leucogranite belts, South Tibet. Science China Earth Sciences, 60, 1655–1663.Suche in Google Scholar

Watson, E.B., and Harrison, T.M. (1983) Zircon saturation revisited: temperature and composition effects in a variety of crustal magma types. Earth and Planetary Science Letters, 64, 295–304.Suche in Google Scholar

Wu, F.Y., Liu, X.C., Liu, Z.C., Wang, R.C., Xie, L., Wang, J.M., Ji, W.Q., Yang, L., Liu, C., Khanal, G.P., and He, S.X. (2020) Highly fractionated Himalayan leucogranites and associated rare-metal mineralization. Lithos, 352-353, 105319.Suche in Google Scholar

Xiang, L., Romer, R.L., Glodny, J., Trumbull, R.B., and Wang, R.C. (2020) Li and B isotopic fractionation at the magmatic-hydrothermal transition of highly evolved granites. Lithos, 376-377, 105753.Suche in Google Scholar

Yang, L. (2020) Research on the relationship between anatexis and petrogenesis of leucogranite in the Himalayan orogenic belt, 256 p. Ph.D. thesis, Beijing, Institute of Geology and Geophysics Chinese Academy of Sciences.Suche in Google Scholar

Zaraisky, G.P., Aksyuk, A.M., Devyatova, V.N., Udoratina, O.V., and Chevychelov, V.Y. (2009) The Zr/Hf ratio as a fractionation indicator of rare-metal granites. Petrology, 17, 25–45.Suche in Google Scholar

Zhang, S.T., Ma, D.S., Lu, J.J., Zhang, R.Q., Cai, Y., and Ding, C.C. (2016) Geochronology, Hf Isotopic Compositions and Geochemical Characteristics of the Pingying Granite Pluton in Northern Guangxi, South China, and Its Geological Significance (in Chinese with English abstract). Geological Journal of China Universities, 22, 92–104.Suche in Google Scholar

Zhang, F., Wang, Y.B., and Yang, D.T. (2020) Zircon U-Pb, O isotope, and geochemistry study of the early Palaeozoic granitic gneiss in the Dinggye district, central Himalaya: Implications for the early Palaeozoic orogenic event along the northern margin of Gondwana. Geological Journal, 55, 439–456.Suche in Google Scholar

Zhu, D.C., Wang, Q., Zhao, Z.D., Chung, S.L., Cawood, P.A., Niu, Y.L., Liu, S.A., Wu, F.Y., and Mo, X.X. (2015) Magmatic record of India-Asia collision. Scientific Reports, 5, 14289–14289.Suche in Google Scholar

Received: 2021-10-14

Accepted: 2022-01-13

Published Online: 2023-01-03

Published in Print: 2023-01-27

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Himalayan leucogranite; beryllium; beryl; source; fractionation; delayed crystallization; Lithium, beryllium and boron: Quintessentially crustal