Controlling crystallisation and dissolution of biogenic CaCO3via dissolved magnesium cations†

IF 3.5 Q3 ENGINEERING, ENVIRONMENTAL
Toby Morton-Collings, Minjun Yang and Richard G. Compton
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引用次数: 0

Abstract

The surface of our oceans is teeming with single-cellular ‘plant’ organisms that biomineralise CaCO3 (coccoliths). Globally, an estimate of over 1015 g of atmospheric CO2 per annum is sequestered in the top layers of our ocean. Information of this process is crucial to modelling climate change and achieving net carbon neutrality not least because this rate of CO2 sequestration is comparable to the rate of anthropogenic release of CO2. While the dissolution kinetics of pure calcite (Icelandic Spar, Carrea marble and synthetically grown) have been well-studied in the past decades it remains unclear if biogenic CaCO3 behaves differently, or not, to pure calcite in the marine environment. In this work, we utilise a light microscopy setup to study and compare the precipitation and dissolution of biogenic CaCO3 in both the absence and presence of Mg2+, a known inhibitor, at concentrations similar to seawater. Notably, the time required for a micron-sized calcite particle to dissolve is doubled by approximately doubling the concentration of Mg2+ from 54.6 mM to 100 mM. The work produces two new, key insights. First, there is negligible difference between the rate of mass loss of biogenic and pure, laboratory grown CaCO3 particles when placed in solutions supersaturated and undersaturated with respect to calcite. Second, the mass of the individual micron-sized biogenic coccoliths, ranging from 100–600 picograms, was inferred via image analysis of data from the complete dissolution of coccoliths in aqueous solutions containing seawater levels of Mg2+. This relatively simple light-based approach, allowing the mass of biogenic CaCO3 platelets to be estimated at the single-entity level, shows promise for the development of a proof-of-concept sensor allowing CaCO3 sequestration to be monitored real-time in our oceans.

Abstract Image

通过溶解的镁阳离子控制生物 CaCO3 的结晶和溶解
海洋表面生长着许多单细胞 "植物 "生物,它们将 CaCO3(茧石)生物矿化。据估计,全球每年有超过 1015 克的大气二氧化碳被封存在海洋表层。有关这一过程的信息对于模拟气候变化和实现净碳中和至关重要,尤其是因为这一二氧化碳螯合速率与人为释放二氧化碳的速率相当。在过去的几十年中,对纯方解石(冰岛斯帕石、卡雷亚大理石和合成方解石)的溶解动力学进行了深入研究,但仍不清楚生物源 CaCO3 在海洋环境中的表现是否与纯方解石不同。在这项工作中,我们利用光学显微镜装置研究和比较了在没有和有 Mg2+(一种已知的抑制剂)的情况下生物 CaCO3 的沉淀和溶解,其浓度与海水相似。值得注意的是,将 Mg2+ 的浓度从 54.6 mM 提高到 100 mM,微米大小的方解石颗粒溶解所需的时间就会增加一倍左右。这项研究提出了两个新的关键见解。首先,将生物源 CaCO3 颗粒和实验室培育的纯 CaCO3 颗粒放入方解石过饱和和欠饱和溶液中,其质量损失率的差异可以忽略不计。其次,通过对含有海水 Mg2+ 水平的水溶液中钙钛矿完全溶解的数据进行图像分析,推断出单个微米级生物钙钛矿的质量(100 - 600 皮克)。这种基于光的方法相对简单,可在单个实体水平上估算生物 CaCO3 微粒的质量,有望开发出概念验证传感器,对海洋中的 CaCO3 封存情况进行实时监测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.90
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