Building amorphous calcium carbonate into geochemical biomineralisation models

Amorphous calcium carbonate (ACC) has been observed, or inferred to exist, in the majority of the major phyla of marine calcifying organisms. The CaCO3 produced by these organisms represents one of the largest long-term carbon sinks on Earth&#8217;s surface, such that identifying how calcification will respond to anthropogenic climate change is an urgent priority. A substantial portion of our knowledge of the biomineralisation process of these organisms is derived from inferences based on skeletal geochemical data, yet such models typically do not include an ACC component because little is known about trace element and isotope fractionation into ACC. In order to address this, we present, to our knowledge, the first structural and geochemical data of ACC precipitated from seawater under varying carbonate system conditions, seawater Mg/Ca ratios, and in the presence of three of the most common intracrystalline amino acids (aspartic acid, glutamic acid, and glycine). Based on these data we identify the carbonate system conditions necessary to produce ACC from seawater [Evans et al., 2019], and identify the dominant controls on ACC geochemistry. As an example, we utilise these data to build a simple biomineralisation model for the low-Mg (e.g. planktonic) foraminifera, based on precipitation of low-Mg calcite through an ACC precursor phase in a semi-enclosed pool. This exercise demonstrates that the observed shell geochemistry of this group of organisms can be fully reconciled with a model that includes an ACC component, and moreover that constraints can be placed on the degree of ACC utilisation and the ACC-calcite transformation process. More broadly, the exercise demonstrates that knowledge of the characteristics and geochemistry of ACC is important in the development of a process-based understanding of marine calcification.Evans, D., Webb, P., Penkman, K. Kr&#246;ger, R., & Allison, N. [2019] The Characteristics and Biological Relevance of Inorganic Amorphous Calcium Carbonate (ACC) Precipitated from Seawater. Crystal Growth & Design 19: 4300.

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Mollusc larval shell formation: amorphous calcium carbonate is a precursor phase for aragonite

Journal of Experimental Zoology ◽

10.1002/jez.90004 ◽

2002 ◽

Vol 293 (5) ◽

pp. 478-491 ◽

Cited By ~ 410

Author(s):

Ingrid Maria Weiss ◽

Noreen Tuross ◽

Lia Addadi ◽

Steve Weiner

Keyword(s):

Calcium Carbonate ◽

Larval Shell ◽

Shell Formation ◽

Amorphous Calcium Carbonate ◽

Precursor Phase

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Microstructure and Relative Humidity Effects on Long-Term Indentation Creep Properties of Calcium Carbonate Cement

10.20944/preprints201810.0671.v1 ◽

2018 ◽

Cited By ~ 2

Author(s):

Jesús Rodríguez-Sánchez ◽

Qing Zhang ◽

Dag Kristian Dysthe

Keyword(s):

Elastic Modulus ◽

Calcium Carbonate ◽

Relative Humidity ◽

Indentation Creep ◽

Amorphous Calcium Carbonate ◽

Creep Properties ◽

Carbonate Cement ◽

Creep Modulus ◽

Term Creep

This paper addresses the effect of both microstructure and relative humidity on the long-term creep properties of sustainable calcium carbonate (CaCO3) cements. Those can be prepared by mixing amorphous calcium carbonate and vaterite with water. A larger starting amount of vaterite, XV, within the mixture design gives a higher elasticity and resistance to the specimens due to the larger overall bridging area within the newly formed calcite crystals. Regarding creep properties for a given relative humidity, the amplitude of creep strain decreases with XV, and makes the relation between the elastic modulus, E, and hardness, H, of the samples to be linear with the contact creep modulus, C. On the other hand, for a given composition, the amplitude of creep increases with the relative humidity, making the contact creep modulus, Ci, to rise exponentially with the elastic modulus, E, and hardness, H, of the specimens. The most probable creep mechanisms for this kind of cement seem to be a combination of microcraking in the early stages and dissolution and reprecipitation of calcite in the long-term (also known as pressure solution theory). The presence of water in pores with increasing relative humidity might enhance the local dissolution of calcite, and hence the creep amplitude.

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Bio-mineralisation, characterization, and stability of calcium carbonate containing organic matter

RSC Advances ◽

10.1039/d1ra00615k ◽

2021 ◽

Vol 11 (24) ◽

pp. 14415-14425

Author(s):

Renlu Liu ◽

Shanshan Huang ◽

Xiaowen Zhang ◽

Yongsheng Song ◽

Genhe He ◽

...

Keyword(s):

Thermal Stability ◽

Organic Matter ◽

Calcium Carbonate ◽

Water Stability ◽

Amorphous Calcium Carbonate

The amorphous calcium carbonate (ACC) or polycrystalline vaterite, which has long-term water stability and thermal stability, can be induced by bacteria. These biogenic CaCO3 are organo-mineral complexes.

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Structural Characterization of the Transient Amorphous Calcium Carbonate Precursor Phase in Sea Urchin Embryos

Advanced Functional Materials ◽

10.1002/adfm.200600134 ◽

2006 ◽

Vol 16 (10) ◽

pp. 1289-1298 ◽

Cited By ~ 156

Author(s):

Y. Politi ◽

Y. Levi-Kalisman ◽

S. Raz ◽

F. Wilt ◽

L. Addadi ◽

...

Keyword(s):

Calcium Carbonate ◽

Sea Urchin ◽

Structural Characterization ◽

Amorphous Calcium Carbonate ◽

Sea Urchin Embryos ◽

Precursor Phase ◽

Carbonate Precursor

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Long-term Stabilized Amorphous Calcium Carbonate – an Ink for Bio-inspired 3D Printing

10.26434/chemrxiv.14439548 ◽

2021 ◽

Author(s):

Hadar Shaked ◽

Iryna Polishchuk ◽

alina nagel ◽

Yehonadav Bekenstein ◽

Boaz Pokroy

Keyword(s):

Mechanical Properties ◽

Calcium Carbonate ◽

3D Printing ◽

Crystalline Lattice ◽

High Yield ◽

Great Promise ◽

Amorphous Precursor ◽

Amorphous Calcium Carbonate ◽

Co Precipitation

Amorphous Calcium Carbonate (ACC) is a highly unstable amorphous precursor many organisms utilize for the formation of crystals with intricate morphology and improved mechanical properties. Herein, we report for the first-time high-yield long-term stabilization of ACC, achieved via its co-precipitation in the presence of high amounts of Mg and an acetone-based storage protocol. A novel use of the formed high-Mg ACC paste as an ink for 3D printing techniques allows the formation of bio-inspired intricately shaped calcium carbonate geometries. The obtained ink can dry, though retains its amorphous nature, at a variety of temperatures ranging from 25 to 150˚C enabling various applications such as cultural heritage reconstruction and artificial reefs formation. We also show the on-demand low-temperature crystallization of the 3D printed ACC models, similar to what is achieved by organisms in nature. Using this bio-inspired crystallization route via transient amorphous precursor also enables the presence of high Mg levels within the calcite crystalline lattice, far beyond the thermodynamically stable solubility level. High levels of Mg incorporation, in turns, encompasses a great promise for the enhancement in the mechanical properties of the crystallized calcite 3D objects akin naturally found crystalline CaCO3.

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The Gulf of St. Lawrence Biogeochemical Model: A Modelling Tool for Fisheries and Ocean Management

Frontiers in Marine Science ◽

10.3389/fmars.2021.732269 ◽

2021 ◽

Vol 8 ◽

Author(s):

Diane Lavoie ◽

Nicolas Lambert ◽

Michel Starr ◽

Joël Chassé ◽

Olivier Riche ◽

...

Keyword(s):

Calcium Carbonate ◽

Dissolved Oxygen ◽

Phytoplankton Bloom ◽

Biogeochemical Model ◽

Carbonate System ◽

Lawrence Estuary ◽

Ocean Management ◽

System Components ◽

St Lawrence Estuary

The goal of this paper is to give a detailed description of the coupled physical-biogeochemical model of the Gulf of St. Lawrence that includes dissolved oxygen and carbonate system components, as well as a detailed analysis of the riverine contribution for different nitrogen and carbonate system components. A particular attention was paid to the representation of the microbial loop in order to maintain the appropriate level of the different biogeochemical components within the system over long term simulations. The skill of the model is demonstrated using in situ data, satellite data and estimated fluxes from different studies based on observational data. The model reproduces the main features of the system such as the phytoplankton bloom, hypoxic areas, pH and calcium carbonate saturation states. The model also reproduces well the estimated transport of nitrate from one region to the other. We revisited previous estimates of the riverine nutrient contribution to surface nitrate in the Lower St. Lawrence Estuary using the model. We also explain the mechanisms that lead to high ammonium concentrations, low dissolved oxygen, and undersaturated calcium carbonate conditions on the Magdalen Shallows.

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