Takashi Sambuichi, U. Tsunogai, Kazushige Kura, F. Nakagawa, T. Ohba
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引用次数: 3
摘要
已经报道了与海水和大气水等水圈H2O相比,陆相硅酸盐的17o损耗(Pack et al., 2016;Sharp et al., 2016)。地幔源硅酸盐的∆′17O值为-70 ~ -30 × 10−6;而大气水的平均∆′17O值为+33 × 10−6,不同深度海水的平均∆′17O值为-5±1 × 10−6 (Luz和Barkan, 2010)。早期原始地球岩浆海洋脱气过程中氧同位素的动力学分选(Tanaka and Nakamura, 2013)或海水与海底玄武岩和大陆地壳等岩石圈组分之间的氧同位素交换(Pack and Herwartz, 2014;Sengupta等人,2020;Sengupta和Pack, 2018)。后一种解释是基于平衡分馏指数θ [=ln17α/ln18α;αA-B = RA/ RB,其中iR对应重同位素(iO, i = 17或18)与轻同位素(16O)的丰度比。在VSMOW-SLAP尺度上对地热H2O和MORB的高精度∆′17O测量:岩石圈和水圈之间的活氧交换的证据
High-precision Δ′17O measurements of geothermal H2O and MORB on the VSMOW-SLAP scale: evidence for active oxygen exchange between the lithosphere and hydrosphere
have reported 17O-depletion in terrestrial silicates compared with that in hydrospheric H2O such as seawater and meteoric water (Pack et al., 2016; Sharp et al., 2016). The ∆′17O value of mantle-derived silicates ranges from –70 to –30 × 10−6; however, the mean ∆′17O value of meteoric water is +33 × 10−6 and that of seawater collected at various depths is –5 ± 1 × 10−6 (Luz and Barkan, 2010). This difference in ∆′17O between the lithosphere and hydrosphere has been explained by kinetic fractionation of oxygen isotopes during degassing from the magma ocean on the early primitive earth (Tanaka and Nakamura, 2013) or oxygen isotope exchange between the seawater and lithospheric components such as seafloor basalt and continental crust (Pack and Herwartz, 2014; Sengupta et al., 2020; Sengupta and Pack, 2018). The latter explanation has been proposed on the basis of findings that the equilibrium fractionation exponent θ [=ln17α/ln18α; αA-B = RA/ RB where iR corresponds to the abundance ratio of the heavy isotope (iO where i = 17 or 18) to the light isotope (16O).] between silicates and H2O is a funcHigh-precision ∆′17O measurements of geothermal H2O and MORB on the VSMOW-SLAP scale: evidence for active oxygen exchange between the lithosphere and hydrosphere
期刊介绍:
Geochemical Journal is an international journal devoted to original research papers in geochemistry and cosmochemistry. It is the primary journal of the Geochemical Society of Japan. Areas of research are as follows:
Cosmochemistry; Mineral and Rock Chemistry; Volcanology and Hydrothermal Chemistry; Isotope Geochemistry and Geochronology; Atmospheric Chemistry; Hydro- and Marine Chemistry; Organic Geochemistry; Environmental Chemistry.