Hydrothermal alteration of aragonitic biocarbonates: assessment of micro- and nanostructural dissolution–reprecipitation and constraints of diagenetic overprint from quantitative statistical grain-area analysis

Casella, Laura A.; He, Sixin; Griesshaber, Erika; Fernández-Díaz, Lourdes; Greiner, Martina; Harper, Elizabeth M.; Ziegler, Andreas; Mavromatis, Vasileios; Dietzel, Martin; Eisenhauer, Anton; Veintemillas‐Verdaguer, S.; Brand, Uwe; Schmahl, Wolfgang W.

doi:10.5194/bg-15-7451-2018

Cited by 22 publications

(68 citation statements)

References 105 publications

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“…This type of information is increasingly reconstructed from bivalve shells [4][5][6], specifically stable oxygen isotope (δ 18 O shell ) values [7][8][9]. Given known limitations of this paleothermometer, i.e., vulnerability to diagenetic overprint [10] and difficulties to obtain δ 18 O water signatures of ancient and/or coastal water bodies, the search for alternative temperature proxies is in full swing (Δ 47 : [11,12]; Δ 48 : [13]; Mg, Sr: [14]). A highly promising candidate is the shell microstructure [15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Temperature-induced microstructural changes in shells of laboratory-grown Arctica islandica (Bivalvia)

Höche¹,

Walliser²,

Winter

et al. 2021

PLoS ONE

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Bivalve shells are increasingly used as archives for high-resolution paleoclimate analyses. However, there is still an urgent need for quantitative temperature proxies that work without knowledge of the water chemistry–as is required for δ18O-based paleothermometry–and can better withstand diagenetic overprint. Recently, microstructural properties have been identified as a potential candidate fulfilling these requirements. So far, only few different microstructure categories (nacreous, prismatic and crossed-lamellar) of some short-lived species have been studied in detail, and in all such studies, the size and/or shape of individual biomineral units was found to increase with water temperature. Here, we explore whether the same applies to properties of the crossed-acicular microstructure in the hinge plate of Arctica islandica, the microstructurally most uniform shell portion in this species. In order to focus solely on the effect of temperature on microstructural properties, this study uses bivalves that grew their shells under controlled temperature conditions (1, 3, 6, 9, 12 and 15°C) in the laboratory. With increasing temperature, the size of the largest individual biomineral units and the relative proportion of shell occupied by the crystalline phase increased. The size of the largest pores, a specific microstructural feature of A. islandica, whose potential role in biomineralization is discussed here, increased exponentially with culturing temperature. This study employs scanning electron microscopy in combination with automated image processing software, including an innovative machine learning–based image segmentation method. The new method greatly facilitates the recognition of microstructural entities and enables a faster and more reliable microstructural analysis than previously used techniques. Results of this study establish the new microstructural temperature proxy in the crossed-acicular microstructures of A. islandica and point to an overarching control mechanism of temperature on the micrometer-scale architecture of bivalve shells across species boundaries.

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Section: Introductionmentioning

confidence: 99%

Temperature-induced microstructural changes in shells of laboratory-grown Arctica islandica (Bivalvia)

Höche¹,

Walliser²,

Winter

et al. 2021

PLoS ONE

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“…The common carbonate archive, Porites sp. corals, have been extensively documented in the literature (Pätzold, ; Allison, ; Stanley & Swart, ; Alibert & McCulloch, ; Enmar et al, ; Felis, Patzold, & Loya, ; McGregor & Gagan, ; Al‐Rousan, Felis, Manasrah, & Al‐Horani, ; Hendy, Gagan, Lough, McCulloch, & DeMenocal, ; McGregor & Abram, ; Benzerara et al, ; Motai et al, ; Lazareth et al, ; Casella et al, ). Due to the geographical range of Porites sp., it has been found to primarily record environmental information in tropical and subtropical regions (Schlager, ; Veron et al, ; Milliman, Muller, & Forstner, ).…”

Section: Introductionmentioning

confidence: 99%

Significance of fluid chemistry throughout diagenesis of aragonitic Porites corals – An experimental approach

Pederson

Weiss

Mavromatis

et al. 2019

The Depositional Record

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Marine carbonates are among the most important archives of environmental information in both modern and past environments. Widely used but particularly sensitive archives are the aragonitic skeletons of scleractinian corals. However, due to the metastable nature of aragonite, a multitude of chemical, mineralogical, and (micro)biological processes can lead to diagenetic alteration of these archives and their proxy information can be altered or lost. Here, hydrothermal alteration experiments were performed to create a better understanding of the diagenesis of an often‐utilized genus, Porites. Same‐specimen subsamples were heated in two fluid types and at two temperatures and durations, and their resulting alteration features were assessed to allow insight to the mechanisms and drivers of diagenetic modification. Experiments with fluid temperatures of 130°C induced remobilization and darkening of organic matrices, with no other evidence for alteration observed. In contrast, specimens exposed to a temperature of 160°C underwent significant diagenetic alteration dependent on fluid type. Fluid chemistry, particularly Mg/Ca ratios, was found to regulate the type of alteration (e.g. neomorphism or reprecipitation). Reaction with meteoric water resulted in almost complete neomorphism of the aragonite skeleton to blocky calcite, as well as significant exchange with the experimental fluid. In comparison, samples altered in the experimental burial fluids record no mineralogic or significant isotopic change, but instead, small‐scale dissolution–reprecipitation of the primary skeleton, along with the precipitation of pore‐filling aragonitic needle cements was observed. The δ18Ocarbonate data indicate transformation via dissolution–reprecipitation mechanisms depending on the degree and mechanism of diagenesis, and are strongly dependent on fluid chemistry. The main outcome of this work is that a multi‐proxy approach has the best potential to shed light on the interpretation of processes and pathways of aragonitic coral alteration. This study has implications for early alteration of carbonate archives within varying diagenetic fluids, with results aiding in the identification of past burial conditions.

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“…The used fluid composition (100 mM NaCl + 10 mM MgCl2) simulates the fluid present at a burial diagenetic realm. The composition of the fluid was identical to that previously used by Casella et al, (2017Casella et al, ( , 2018 and Pederson et al, (2019a;2019b;2020) in their hydrothermal alteration experiments.…”

Section: Hydrothermal Alteration Experimentsmentioning

confidence: 92%

“…consist entirely of aragonite according to XRD measurements and Rietveld analysis (Fig. A2 and A4 from Casella et al, 2018) and have an organic matter content that varies significantly for the different species. Organic matter concentration in the investigated hard tissues was determined with TGA analyses (Fig.…”

Section: Grain Area/size Statistical Evaluationmentioning

confidence: 99%

“…Aiming to understand the influence of bioaragonite architecture in the kinetics of hydrothermal alteration we investigated the alteration response of three very different biocarbonate skeletons: (i) the granular aragonite that forms the shell of the bivalve Arctica islandica, (ii) the prismatic and columnar nacreous aragonite that comprises the shell of the gastropod Haliotis ovina and (iii) the acicular, fibrous aragonite that builds up the skeleton of the coral Porites sp. By comparing the hydrothermal overprint undergone by these microstructures after prolonged alteration at 80ºC (this study) and after much shorter alteration at 175 °C (Casella et al, 2018) we better identify early hydrothermal alterations steps and improve our understanding of the role of temperature and time in the progress of alteration overprint. This study demonstrates that a combination of analytical tools and evaluation techniques (TGA and XRD measurements, Rietveld analysis of XRD data, EBSD measurements and grain size statistical evaluation, laser confocal microscopy, FE-SEM and AFM imaging) provides the ideal set of data to pinpoint the structural changes caused by the hydrothermal and/or diagenetic alteration of biological hard tissues, even the subtle, difficult to address ones that mark the very first steps of biocarbonate microstructural reorganization.…”

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confidence: 99%

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Long-term experimental diagenesis of aragonitic biocarbonates: from organic matter loss to abiogenic calcite formation

Forjanes

Roda

Greiner

et al. 2021

Preprint

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Abstract. Carbonate biological hard tissues are valuable archives of environmental information. However, this information can be blurred or even completely lost as hard tissues undergo diagenetic alteration. This is more likely to occur in aragonitic skeletons because bioaragonite commonly transforms into calcite during diagenesis. For reliably using aragonitic skeletons as geochemical proxies, it is necessary to understand in depth the diagenetic alteration processes that they undergo. Several works have recently investigated the hydrothermal alteration of aragonitic hard tissues during short term experiments at high temperatures (T > 160 °C). In this study, we conduct long term (4 and 6 months) hydrothermal alteration experiments at 80 °C using burial-like fluids. We document and evaluate the changes undergone by the outer and inner layers of Arctica islandica shell, the prismatic and nacreous layers of Haliotis ovina shell, and the skeleton of Porites sp. combining a variety of analytical tools (X-ray diffraction, thermogravimetry analysis, laser confocal microscopy, scanning electron microscopy, electron backscatter diffraction and atomic force microscopy). We demonstrate that this approach is the most adequate to trace subtle, diagenetic alteration-related changes in aragonitic biocarbonates. Furthermore, we unveil that the diagenetic alteration of aragonitic hard tissues is a complex multi-step process where major changes occur even at the low temperature used in this study and well before any aragonite into calcite transformation takes place. Alteration starts with biopolymer decomposition and concomitant generation of secondary porosity. These processes are followed by abiogenic aragonite precipitation that partially or totally obliterates the secondary porosity. Only afterwards any transformation of aragonite into calcite takes place. The kinetics of the alteration is highly dependent on primary microstructural features of the aragonitic biomineral. While the skeleton of Porites sp. remains virtually unaltered within the time spam of the experiments, Haliotis ovina nacre undergoes extensive abiogenic aragonite precipitation, the outer and inner layers of Arctica islandica shell are significantly affected by aragonite transformation into calcite and this transformations extensive in the case of the prismatic layer of Haliotis ovina shell. Our results suggest that most aragonitic fossil archives may be overprinted, even those free of clear diagenetic alteration signs. This finding may have major implications for the use of these archives as geochemical proxies.

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Hydrothermal alteration of aragonitic biocarbonates: assessment of micro- and nanostructural dissolution–reprecipitation and constraints of diagenetic overprint from quantitative statistical grain-area analysis

Cited by 22 publications

References 105 publications

Temperature-induced microstructural changes in shells of laboratory-grown Arctica islandica (Bivalvia)

Temperature-induced microstructural changes in shells of laboratory-grown Arctica islandica (Bivalvia)

Significance of fluid chemistry throughout diagenesis of aragonitic Porites corals – An experimental approach

Long-term experimental diagenesis of aragonitic biocarbonates: from organic matter loss to abiogenic calcite formation

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