Data Paper. Data Paper

File List Full_trace_elemental_concentrations_ratios_Echinodermata.csv (MD5: e3aca29305b72ec8d8bf23204237e639) Full_trace_elemental_concentrations_ratios_latitude_Echinodermata.csv (MD5: 5bab247412aad7047f36064c5aba4e9c) Description Biogenic carbonate production in benthic marine ecosystems is domin...

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Bibliographic Details
Main Authors: M. Lebrato, J. B. McClintock, M. O. Amsler, J. B. Ries, H. Egilsdottir, M. Lamare, C. D. Amsler, R. C. Challener, J. B. Schram, C. L. Mah, J. Cuce, B. J. Baker
Format: Dataset
Language:unknown
Published: Wiley 2016
Subjects:
Environmental Science
Ecology
FOS Biological sciences
Antarctic
Arctic
Dy
The Antarctic
Antarc*
Ocean acidification
Online Access:https://dx.doi.org/10.6084/m9.figshare.3556776
https://wiley.figshare.com/articles/dataset/Data_Paper_Data_Paper/3556776
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Summary:File List Full_trace_elemental_concentrations_ratios_Echinodermata.csv (MD5: e3aca29305b72ec8d8bf23204237e639) Full_trace_elemental_concentrations_ratios_latitude_Echinodermata.csv (MD5: 5bab247412aad7047f36064c5aba4e9c) Description Biogenic carbonate production in benthic marine ecosystems is dominated by representatives of the Echinodermata. Carbon and other major, minor, and trace elements are exported to the seabed where they accumulate or dissolve. Preserved carbonates (Mg-calcite) have applications in oceanography and geochemistry and are used to reconstruct various parameters of ancient seawater, such as temperature (from Mg/Ca, Sr/Ca), seawater Mg/Ca (from Mg/Ca), and pH (from B/Ca). In general, the benthos is widely ignored for its role in the global carbon cycle despite the importance of echinoderms as a carbon sink (~ 0.1–0.2 Pg C/yr). Echinoderms produce their skeletons from Mg-calcite, which is more soluble than pure calcite and, therefore, more vulnerable to ocean acidification (OA). Little is known about the concentration of minor and trace elements within their tests, which can also destabilize the calcite lattice increasing the mineral’s solubility. Expanding our knowledge on their composition will improve our understanding of elemental flux in the oceans. Furthermore, establishing relationships between the physical parameters of seawater and minor/trace elemental ratios within echinoderm Mg-calcite should expand the utility of fossils, renowned for their high-quality preservation as geochemical archives. Herein, we present elemental composition data for Asteroidea ( n = 108; 9 families, 23 species), Echinoidea ( n = 94; 8 families, 12 species), Ophiuroidea ( n = 24; 4 families, 5 species), Holothuroidea ( n = 7; 3 families, 3 species), and Crinoidea ( n = 3; 1 family, 1 species), collected from the Arctic to the Antarctic Oceans, from depths ranging from surface waters to 1200 m. The following elements were measured and normalized to [Ca]: Li, Be, Mg, Al, P, S, K, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, As, Se, Rb, Sr, Y, Zr, Mo, Ag, Cd, Sn, Sb, Te, Ba, La, Ce, Nd, Dy, W, Re, Au, Hg, Tl, Pb, Bi, and U. Data are presented for the whole body, arms (plates), calcareous ossicles, spines, and test plates. Elements were quantified using inductively coupled plasma mass spectrometry. Our study presents the most comprehensive data set to date for a phylum whose skeletons are composed of Mg-calcite. Key words: biomineralization; calcification; carbonate; Echinodermata; elemental composition; ICPMS; Mg-calcite; minor elements; ocean acidification; paleoceanography; paleoproxies; trace elements.

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