Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
8910606 | Geochimica et Cosmochimica Acta | 2018 | 17 Pages |
Abstract
To investigate the behavior of Mg isotopes during low-temperature alteration of oceanic crust and to further understand its role in the global Mg cycle, we measured the Mg isotopic compositions (25Mg/24Mg and 26Mg/24Mg) of a set of samples of altered oceanic crust (AOC) recovered from the Ocean Drilling Program Hole 801C, the reference site for old crust (â¼170â¯Ma) subducting in the Pacific. The measured δ26Mg values range from â1.70â° to 0.21â°, deviating from that of pristine oceanic basalts (â0.25â¯Â±â¯0.07â°). Composite samples of volcanoclastic breccia that have experienced relatively intense alteration have larger variation in δ26Mg values (â1.01â° to 0.15â°) than composite samples of massive basaltic flows (â0.53â° to â0.04â°), indicating significant Mg isotope fractionation during low-temperature alteration of the oceanic crust. Moreover, the upper off-axis basement has on average lower δ26Mg values (â1.70â° to â0.04â°) than the lower on-axis basement (â0.16â° to 0.21â°). These findings, combined with the co-variations between MgO content and FeOâ/CaO ratio and between δ26Mg and FeOâ/CaO ratio, suggest that formation of Mg-bearing minerals (i.e., saponite and calcite) during low-temperature alteration of the oceanic crust accounts for the highly variable δ26Mg of AOC. Early formation of saponite under anoxic condition preferentially takes up heavy Mg isotopes and accounts for Mg enrichment and relatively high δ26Mg in the on-axis basement. Subsequent precipitation of carbonates results in the dilution of Mg and relatively low δ26Mg in the off-axis basement. In addition, accumulation of carbonate-rich interflow sediments in the upper basement may contribute further to the low δ26Mg. A weighted average δ26Mg value of 0.00â¯Â±â¯0.09â° is estimated for the AOC at Site 801, implying that low-temperature alteration of oceanic crust drives the ocean to a lighter Mg isotopic composition, and thus requires additional carbonate precipitation to maintain a steady-state Mg isotopic composition of seawater. A mass balance calculation suggests that the Mg output flux due to low-temperature alteration of the oceanic crust equals â¼12% of the annual Mg riverine input, indicating that AOC is a significant sink of Mg in seawater. Our study further highlights that recycling of AOC with highly variable δ26Mg along with overlying marine sediments into the mantle through subduction may generate Mg isotopic heterogeneity in the mantle at small scales.
Related Topics
Physical Sciences and Engineering
Earth and Planetary Sciences
Geochemistry and Petrology
Authors
Kang-Jun Huang, Fang-Zhen Teng, Terry Plank, Hubert Staudigel, Yan Hu, Zheng-Yu Bao,