Tracing the migration and extreme enrichment of critical metals using metal-stable isotopes

被引:0
|
作者
Hu X. [1 ]
Deng G. [1 ]
Chen X. [1 ]
Sheng J. [1 ]
Huang F. [1 ,2 ]
机构
[1] CAS Key Laboratory of Crust-Mantle Materials and Environments, School of Earth and Space Sciences University of Science and Technology of China, Anhui, Hefei
[2] CAS Center for Excellence in Comparative Planetology, Anhui, Hefei
来源
Dizhi Xuebao/Acta Geologica Sinica | 2024年 / 98卷 / 05期
关键词
critical metals; isotope tracing; magmatic-hydrothcrmal processes; stable metal isotopes; supernormal enrichment;
D O I
10.19762/j.cnki.dizhixuebao.2024085
中图分类号
学科分类号
摘要
Critical metal minerals arc significant to the national economy and security, but whether their enrichment is controlled by the fractional crystallization process or by the magmatic-hydrothcrmal interaction remains controversial. Traditional geochemical methods can only indirectly restrict the source of ore-forming materials, and it isn't easy to distinguish the effects of fractional crystallization and magmatic-hydrothermal processes on mineralization. The isotope systems of fluid-active metals such as Rb, Ba, Sr, and U have different responses to these two mechanisms. Wc have studied the Rb and Ba isotopes of granites collected from the Himalayas and South China. Our research shows that the Ba isotope in the residual melt becomes heavier and the Rb isotope remains unchanged during mineral crystallization, while the Ba isotope in the granite becomes lighter and the Rb isotope becomes heavier during the magmatic-hydrothermal interaction. The hydrothermal fluid exsolvcd from deep magma brings abundant critical metals that arc easy to migrate with fluid. Our study shows that stable metal isotopes, especially fluid-active metal isotopes, are very effective in tracing magmatic-hydrothermal processes and ore-forming fluid sources. © 2024 Geological Society of China. All rights reserved.
引用
收藏
页码:1550 / 1572
页数:22
相关论文
共 145 条
  • [1] Amsellem E, Moynier F, Day JMD, Moreira M, Puchtel I S, Teng Fangzhen, The stable strontium isotopic composition of ocean island basalts* mid-ocean ridge basalts* and komatiites, Chemical Geology, 483, pp. 595-602, (2018)
  • [2] Andersen M B, Elliott T, Freymuth H, Sims K W W, Niu Yaolmg, Kelley K A., The terrestrial uranium isotope cycle. Nature, 517(7534). 356 - 359, (2015)
  • [3] Armstrong R L., 19 68. A mode for the evolution of strontium and lead isotopes in a dynamic Earth, Reviews of Geophysics, 6, pp. 175-199
  • [4] Arzilh F, Fahbrizio A, Schmidt M W, Petrelli M, Maimaiti M, Dingwell D B, Pans E, Burton M, Carroll M R., The effect of diffusive re-equilibration time on trace element partitioning between alkali feldspar and trachytic melts, Chemical Geology, 495, pp. 50-66, (2018)
  • [5] Audetat A, Edmonds M., Magmatic-hydrothermal fluids, Elements, 16, 6, pp. 401-406, (2020)
  • [6] Avanzinelli R, Casalini M, Elliott T, Conticelli S., Carbon fluxes from subducted carbonates revealed by uranium excess at Mount Vesuvius, Italy, Geology, 46, 3, pp. 259-262, (2018)
  • [7] Ballouard C, Poujol M, Boulvais P, Branquet Y, Tartese R, Vigneresse J L., Nb-Ta fractionation in peraluminous granites: A marker of the magmatic-hydrothermal transition, Geology, 44, 3, pp. 231-234, (2016)
  • [8] Bau M., Controls on the fractionation of isovalent trace elements in magmatic and aqueous systems
  • [9] Evidence from Y/Ho, Zr/Hf, and lanthanide tetrad effect, Contributions to Mineralogy and Petrology, 123, 3, pp. 323-333, (1996)
  • [10] Bigeleisen J., 199 6. Nuclear size and shape effects in chemical reactions. Isotope chemistry of the heavy elements, Journal of the American Chemical Society, 118, 15, pp. 3676-3680
12345678910