Seth G. John, Hengdi Liang, Benoît Pasquier, Mark Holzer, Sam Silva
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引用次数: 0
摘要
镍(Ni)是一种微量营养元素,在现代海洋的摄氮和固氮过程中发挥作用,并可能影响地质时标上的甲烷生成率。在此,我们介绍了全球海洋镍通量诊断模型的结果,该模型解决了海洋镍循环的关键问题。首先利用观测覆盖率较高的示踪剂(如宏量营养元素),将稀少的镍浓度观测数据外推到全球网格气候学中,并测试三种不同的机器学习技术。然后利用海洋环流反演模式(OCIM2)估算镍的物理传输,揭示净汇聚或发散区域。这些诊断并不基于任何有关镍生物地球化学循环的假设,但其空间模式可用于推断生物镍吸收和再生等生物地球化学过程的发生地。虽然镍和硅酸盐(Si)在海洋中具有相似的浓度模式,但我们发现表层海洋中镍吸收的空间模式与磷酸盐(P)吸收相似,而与硅酸盐(Si)吸收不相似。这表明,它们相似的分布是由不同的生物地球化学机制造成的,这与其他证据表明镍并没有被硅藻壳吸收一致。我们发现,当 Ni 浓度接近 2 nM 时,吸收时的 Ni:P 比率并没有降低,这对表层海洋中存在 2 nM 以下不可生物利用的 Ni 池的假说提出了质疑。最后,我们发现镍的净再生发生在海洋的更深处,而不是钙的净再生发生在海洋的更深处,尽管没有硅的净再生发生在海洋的更深处。
Biogeochemical Fluxes of Nickel in the Global Oceans Inferred From a Diagnostic Model
Nickel (Ni) is a micronutrient that plays a role in nitrogen uptake and fixation in the modern ocean and may have affected rates of methanogenesis on geological timescales. Here, we present the results of a diagnostic model of global ocean Ni fluxes which addresses key questions about marine Ni cycling. Sparsely available observations of Ni concentration are first extrapolated into a global gridded climatology using tracers with better observational coverage such as macronutrients, and testing three different machine learning techniques. The physical transport of Ni is then estimated using the ocean circulation inverse model (OCIM2), revealing regions of net convergence or divergence. These diagnostics are not based on any assumption about Ni biogeochemical cycling, but their spatial patterns can be used to infer where biogeochemical processes such as biological Ni uptake and regeneration take place. Although Ni and silicate (Si) have similar concentration patterns in the ocean, we find that the spatial pattern of Ni uptake in the surface ocean is similar to phosphate (P) uptake but not to silicate (Si) uptake. This suggests that their similar distributions arise from different biogeochemical mechanisms, consistent with other evidence showing that Ni is not incorporated into diatom frustules. We find that Ni:P ratios at uptake do not decrease as Ni concentrations approach 2 nM, which challenges the hypothesis of a ∼2 nM pool of non-bioavailable Ni in the surface ocean. Finally, we find that the net regeneration of Ni occurs deeper in the ocean than for P, though not as deeply as for Si.
期刊介绍:
Global Biogeochemical Cycles (GBC) features research on regional to global biogeochemical interactions, as well as more local studies that demonstrate fundamental implications for biogeochemical processing at regional or global scales. Published papers draw on a wide array of methods and knowledge and extend in time from the deep geologic past to recent historical and potential future interactions. This broad scope includes studies that elucidate human activities as interactive components of biogeochemical cycles and physical Earth Systems including climate. Authors are required to make their work accessible to a broad interdisciplinary range of scientists.