Geochemical and microstructural characterisation of two species of cool-water bivalves (&amp;lt;i&amp;gt;Fulvia tenuicostata&amp;lt;/i&amp;gt; and &amp;lt;i&amp;gt;Soletellina biradiata&amp;lt;/i&amp;gt;) from Western Australia

Roger, Liza M.; George, Annette D.; Shaw, Jeremy; Hart, Robert D.; Roberts, Malcolm P.; Becker, Thomas; McDonald, Bradley J.; Evans, Noreen J.

doi:10.5194/bg-14-1721-2017

Cited by 15 publications

(9 citation statements)

References 57 publications

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“…Comparing our crystallographic findings of deep-sea corals to previous studies, unit cell volumes of live deep-sea corals (227.719-227.927 Å 3 ) fall slightly above the range of previous X-ray diffraction studies on mollusk (226.4277-227.774 Å 3 ) and coral biogenic aragonites (227.488-227.603 Å 3 ) (Pokroy et al, 2004(Pokroy et al, , 2006(Pokroy et al, , 2007Stolarski et al, 2007;Roger et al, 2017) (Figure 2 and Supplementary Table S3). Average anisotropic axis elongations in corals from this study compared to geological aragonite (Pokroy et al, 2007) agree with elongation ratios from Pokroy et al (2007) along the aand c-axes ( a/a Pokroy = 0.000967, a/a This study = 0.001086; c/c Pokroy = 0.0019, c/c This study = 0.00199), but not along the b-axis in which we observe elongations rather than a shortening as reported by Pokroy et al (2007)…”

Section: Aragonite Crystallography From Corals Of Different Species Asupporting

confidence: 69%

Mineralogy of Deep-Sea Coral Aragonites as a Function of Aragonite Saturation State

et al. 2018

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In an ocean with rapidly changing chemistry, studies have assessed coral skeletal health under projected ocean acidification (OA) scenarios by characterizing morphological distortions in skeletal architecture and measuring bulk properties, such as net calcification and dissolution. Few studies offer more detailed information on skeletal mineralogy. Since aragonite crystallography will at least partially govern the material properties of coral skeletons, such as solubility and strength, it is important to understand how it is influenced by environmental stressors. Here, we take a mineralogical approach using micro X-ray diffraction (XRD) and whole pattern Rietveld refinement analysis to track crystallographic shifts in deep-sea coral Lophelia pertusa samples collected along a natural seawater aragonite saturation state gradient ( sw = 1.15-1.44) in the Gulf of Mexico. Our results reveal statistically significant linear relationships between rising sw and increasing unit cell volume driven by an anisotropic lengthening along the b-axis. These structural changes are similarly observed in synthetic aragonites precipitated under various saturation states, indicating that these changes are inherent to the crystallography of aragonite. Increased crystallographic disorder via widening of the full width at half maximum of the main (111) XRD peaks trend with increased Ba substitutions for Ca, however, trace substitutions by Ba, Sr, and Mg do not trend with crystal lattice parameters in our samples. Instead, we observe a significant trend of increasing calcite content as a function of both decreasing unit cell parameters as well as decreasing sw . This may make calcite incorporation an important factor to consider in coral crystallography, especially under varying aragonite saturation states ( Ar ). Finally, by defining crystallography-based linear relationships between Ar of synthetic aragonite analogs and lattice parameters, we predict internal calcifying fluid saturation state ( cf = 11.1-17.3 calculated from b-axis lengths; 15.2-25.2 calculated from unit cell volumes) for L. pertusa, which may allow this species to calcify despite the local seawater conditions. This study will ideally pave the way for future studies to utilize quantitative XRD in exploring the impact of physical and chemical stressors on biominerals.

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Section: Aragonite Crystallography From Corals Of Different Species Asupporting

confidence: 69%

Mineralogy of Deep-Sea Coral Aragonites as a Function of Aragonite Saturation State

et al. 2018

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“…When light interacts with a material, a small percentage (typically < 0.0001 %) of the photons are scattered inelastically (referred to as Raman or Stokes scattering), resulting in a change of energy and frequency (Smith and Dent, 2005). The frequency shifts associated with Raman scattering are characteristic of both the internal vibrations of a molecule and the lattice vibrations between molecules in a crystal, which makes Raman spectroscopy a valuable tool for mineral identification (Urmos et al, 1991;Dandeu et al, 2006;Brahmi et al, 2010;Clode et al, 2011;Nehrke et al, 2011;Stock et al, 2012;Foster and Clode, 2016;Stolarski et al, 2016;Roger et al, 2017). Importantly, Raman peaks can also provide information regarding the chemical composition of crystals and the conditions of the fluid from which they formed.…”

Section: Introductionmentioning

confidence: 99%

Coral calcifying fluid aragonite saturation states derived from Raman spectroscopy

DeCarlo¹,

D’Olivo²,

Foster³

et al. 2017

Biogeosciences

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Abstract. Quantifying the saturation state of aragonite ( Ar ) within the calcifying fluid of corals is critical for understanding their biomineralization process and sensitivity to environmental changes including ocean acidification. Recent advances in microscopy, microprobes, and isotope geochemistry enable the determination of calcifying fluid pH and [CO ]/K sp ) has proved elusive. Here we test a new technique for deriving Ar based on Raman spectroscopy. First, we analysed abiogenic aragonite crystals precipitated under a range of Ar from 10 to 34, and we found a strong dependence of Raman peak width on Ar with no significant effects of other factors including pH, Mg/Ca partitioning, and temperature. Validation of our Raman technique for corals is difficult because there are presently no direct measurements of calcifying fluid Ar available for comparison. However, Raman analysis of the international coral standard JCp-1 produced Ar of 12.3 ± 0.3, which we demonstrate is consistent with published skeletal Mg/Ca, Sr/Ca, B/Ca, δ 11 B, and δ 44 Ca data. Raman measurements are rapid (≤ 1 s), high-resolution (≤ 1 µm), precise (derived Ar ± 1 to 2 per spectrum depending on instrument configuration), accurate ( ±2 if Ar < 20), and require minimal sample preparation, making the technique well suited for testing the sensitivity of coral calcifying fluid Ar to ocean acidification and warming using samples from natural and laboratory settings. To demonstrate this, we also show a high-resolution time series of Ar over multiple years of growth in a Porites skeleton from the Great Barrier Reef, and we evaluate the response of Ar in juvenile Acropora cultured under elevated CO 2 and temperature.

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“…The frequency shifts associated with Raman scattering are characteristic of both the internal vibrations of a molecule and the lattice vibrations between molecules in a crystal, which makes Raman spectroscopy a valuable tool for mineral identification (Urmos et al, 1991;Dandeu et al, 2006;Brahmi et al, 2010;Clode et al, 2011;Nehrke et al, 2011;Stock et al, 2012;Stolarski et al, 2016;Roger et al, 2017). Importantly, Raman peaks can also provide information regarding the chemical composition of crystals and the conditions of the fluid from which they formed.…”

Section: Introductionmentioning

confidence: 99%

Coral calcifying fluid aragonite saturation states derived from Raman spectroscopy

DeCarlo¹,

D'Olivo²,

Foster³

et al. 2017

Preprint

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Abstract. Quantifying the saturation state of aragonite (&#937;Ar) within the calcifying fluid of corals is critical for understanding their biomineralisation process and sensitivity to environmental changes including ocean acidification. Recent advances in microscopy, microprobes, and isotope geochemistry allow determination of calcifying fluid pH and [CO32&#8722;], but direct quantification of &#937;Ar (where &#937;Ar =[CO32&#8722;][Ca2+]/Ksp) has proved elusive. Here we test a new technique for deriving &#937;Ar based on Raman spectroscopy. First, we analysed abiogenic aragonite crystals precipitated under a range of &#937;Ar from 10 to 34, and found a strong dependence of Raman peak width on &#937;Ar that was independent of other factors including pH, Mg/Ca partitioning, and temperature. Validation of our Raman technique for corals is difficult because there are presently no direct measurements of calcifying fluid &#937;Ar available for comparison. However, Raman analysis of the international coral standard JCp-1 produced &#937;Ar of 12.3&#8201;&#177;&#8201;0.3, which we demonstrate is consistent with published skeletal Sr/Ca, Mg/Ca, B/Ca, &#948;44Ca, and &#948;11B data. Raman measurements are rapid (&#8804;&#8201;1&#8201;s), high-resolution (<&#8201;1&#8201;&#956;m), precise (derived &#937;Ar &#177;1 to 2), and require minimal sample preparation; making the technique well suited for testing the sensitivity of coral calcifying fluid &#937;Ar to ocean acidification and warming using samples from natural and laboratory settings. To demonstrate this, we also show a high-resolution time series of &#937;Ar over multiple years of growth in a Porites skeleton from the Great Barrier Reef, and we evaluate the response of &#937;Ar in juvenile Acropora cultured under elevated CO2 and temperature.

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Geochemical and microstructural characterisation of two species of cool-water bivalves (<i>Fulvia tenuicostata</i> and <i>Soletellina biradiata</i>) from Western Australia

Cited by 15 publications

References 57 publications

Mineralogy of Deep-Sea Coral Aragonites as a Function of Aragonite Saturation State

Mineralogy of Deep-Sea Coral Aragonites as a Function of Aragonite Saturation State

Coral calcifying fluid aragonite saturation states derived from Raman spectroscopy

Coral calcifying fluid aragonite saturation states derived from Raman spectroscopy

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