Competitive dissolution of mixed carbonate solids under simulated ocean acidification

IF 4.5 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Hannah Guiney, Alfonso O. Mucci
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Abstract

It is estimated that at least 25 % of the anthropogenic carbon dioxide (CO2) emitted to the atmosphere since the start of the industrial revolution has been absorbed and dissolved by the oceans. The uptake of CO2 by the oceans leads to an increase in the seawater proton concentration ([H+]), and decreases in seawater pH, carbonate ion concentration ([CO32–]), and saturation state (Ω) with respect to calcium carbonate (CaCO3) minerals; a process commonly referred to as “ocean acidification”. Shallow-water (<200 m), high-magnesium, biogenic calcites are expected to be amongst the first to respond to ocean acidification, and it has been proposed that they will dissolve selectively and sequentially according to their solubility in seawater. In this study, we test this competitive dissolution hypothesis by reacting a mixture of biogenic and synthetic carbonates of varying Mg content with acidified, natural seawater to simulate the progressive acidification of surface-ocean waters by anthropogenic CO2. The results of this study confirm the hypothesis that carbonates will dissolve sequentially according to their respective solubility. They also reveal that the dissolution of high Mg-calcites will proceed incongruently. The originality of this contribution rests with the demonstration that the presence of a single high Mg-calcite will generate, like in a sediment of mixed mineralogy, a continuum of transient states as lower Mg-calcites of greater stability are precipitated and dissolved. Consequently, in a semi-closed or closed system, the pH buffering of the acidified seawater solution will be progressive rather than occur in steps according to changes in the solubility of the individual carbonate phases that compose a sediment. Hence, we expect that, as the oceans take up more anthropogenic CO2 and further acidify, the average mineralogy and composition (Mg content) of shallow-water carbonate sediments and reef structures will change over the next few centuries as the most soluble carbonate phases (high-Mg calcites) are dissolved and no longer precipitated.
模拟海洋酸化条件下混合碳酸盐固体的竞争性溶解
据估计,自工业革命开始以来,人为排放到大气中的二氧化碳(CO2)至少有 25% 被海洋吸收和溶解。海洋吸收二氧化碳导致海水质子浓度([H+])增加,海水 pH 值、碳酸根离子浓度([CO32-])和碳酸钙(CaCO3)矿物质饱和状态(Ω)降低;这一过程通常被称为 "海洋酸化"。浅水(<200 m)高镁生物方解石预计将最先对海洋酸化做出反应,有人提出它们将根据其在海水中的溶解度有选择性地依次溶解。在本研究中,我们通过将不同镁含量的生物碳酸盐和合成碳酸盐混合物与酸化的天然海水反应来模拟人为二氧化碳对海洋表层水的逐步酸化,从而验证了这一竞争性溶解假说。研究结果证实了碳酸盐将根据各自的溶解度依次溶解的假设。研究还发现,高镁方解石的溶解过程并不一致。这项研究的独创性在于证明了单个高镁方解石的存在会像在混合矿物学沉积物中一样,随着稳定性更高的低镁方解石的沉淀和溶解,产生连续的瞬态。因此,在半封闭或封闭系统中,酸化海水溶液的 pH 缓冲作用将是渐进的,而不是根据组成沉积物的各个碳酸盐相溶解度的变化分步进行的。因此,我们预计,随着海洋吸收更多的人为二氧化碳并进一步酸化,浅水碳酸盐沉积物和珊瑚礁结构的平均矿物学和组成(镁含量)将在未来几个世纪中发生变化,因为可溶性最强的碳酸盐相(高镁方解石)被溶解,不再沉淀。
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来源期刊
Geochimica et Cosmochimica Acta
Geochimica et Cosmochimica Acta 地学-地球化学与地球物理
CiteScore
9.60
自引率
14.00%
发文量
437
审稿时长
6 months
期刊介绍: Geochimica et Cosmochimica Acta publishes research papers in a wide range of subjects in terrestrial geochemistry, meteoritics, and planetary geochemistry. The scope of the journal includes: 1). Physical chemistry of gases, aqueous solutions, glasses, and crystalline solids 2). Igneous and metamorphic petrology 3). Chemical processes in the atmosphere, hydrosphere, biosphere, and lithosphere of the Earth 4). Organic geochemistry 5). Isotope geochemistry 6). Meteoritics and meteorite impacts 7). Lunar science; and 8). Planetary geochemistry.
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