Combined Effects of Atmospheric and Seafloor Iron Fluxes to the Glacial Ocean

J. Muglia, C. Somes, L. Nickelsen, A. Schmittner
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引用次数: 21

Abstract

Changes in the ocean iron cycle could help explain the low atmospheric CO2 during the Last Glacial Maximum (LGM). Previous modeling studies have mostly considered changes in aeolian iron fluxes, although it is known that sedimentary and hydrothermal fluxes are important iron sources for today's ocean. Here we explore effects of preindustrial-to-LGM changes in atmospheric dust, sedimentary, and hydrothermal fluxes on the ocean's iron and carbon cycles in a global coupled biogeochemical-circulation model. Considering variable atmospheric iron solubility decreases LGM surface soluble iron fluxes compared with assuming constant solubility. This limits potential increases in productivity and export production due to surface iron fertilization, lowering atmospheric CO2 by only 4 ppm. The effect is countered by a decrease in sedimentary flux due to lower sea level, which increases CO2 by 15 ppm. Assuming a 10 times higher iron dust solubility in the Southern Ocean, combined with changes in sedimentary flux, we obtain an atmospheric CO2 reduction of 13 ppm. The high uncertainty in the iron fluxes does not allow us to determine the net direction and magnitude of variations in atmospheric CO2 due to changes in the iron cycle. Our model does not account for changes to iron-binding ligand concentrations that could modify the results. We conclude that when evaluating glacial-interglacial changes in the ocean iron cycle, not only surface but also seafloor fluxes must be taken into account.
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大气和海底铁通量对冰川海的综合影响
海洋铁循环的变化可能有助于解释上一次冰川盛期(LGM)大气中二氧化碳含量低的原因。先前的建模研究大多考虑了风成铁通量的变化,尽管已知沉积和热液通量是当今海洋的重要铁源。在这里,我们在全球耦合生物地球化学循环模型中探索了大气尘埃、沉积和热液通量的前工业化到LGM变化对海洋铁和碳循环的影响。与假设恒定溶解度相比,考虑大气中铁溶解度的变化会降低LGM表面可溶性铁通量。这限制了由于地表铁施肥而导致的生产力和出口产量的潜在增长,使大气中的二氧化碳含量仅降低了4ppm。由于海平面降低,沉积通量减少,二氧化碳增加了15ppm,抵消了这种影响。假设铁尘在南大洋的溶解度高出10倍,再加上沉积通量的变化,我们获得了13ppm的大气二氧化碳减少量。铁通量的高不确定性使我们无法确定由于铁循环的变化而导致的大气CO2变化的净方向和幅度。我们的模型没有考虑可能改变结果的铁结合配体浓度的变化。我们得出的结论是,在评估海洋铁循环中的冰川-间冰期变化时,不仅必须考虑地表通量,还必须考虑海底通量。
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来源期刊
Paleoceanography
Paleoceanography 地学-地球科学综合
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6-12 weeks
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