Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals

The ocean is a major component of global heat transport and represents a large exchangeable reservoir of CO₂. The importance of these effects on climate can be quantified with records of ocean temperature, chemistry and dynamics spanning past climate change. One approach to reconstruct past ocean co...

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Main Author: Gagnon, Alexander C.
Format: Thesis
Language:English
Published: 2010
Subjects:
Ocean acidification
Online Access:https://thesis.library.caltech.edu/5790/
https://thesis.library.caltech.edu/5790/2/Gagnon_thesis_09_CIT_revised.pdf
https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148
id ftcaltechdiss:oai:thesis.library.caltech.edu:5790
record_format openpolar
spelling ftcaltechdiss:oai:thesis.library.caltech.edu:5790 2023-05-15T17:52:06+02:00 Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals Gagnon, Alexander C. 2010 application/pdf https://thesis.library.caltech.edu/5790/ https://thesis.library.caltech.edu/5790/2/Gagnon_thesis_09_CIT_revised.pdf https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148 en eng https://thesis.library.caltech.edu/5790/2/Gagnon_thesis_09_CIT_revised.pdf Gagnon, Alexander C. (2010) Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/N1MW-8Q84. https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148 <https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148> other Thesis NonPeerReviewed 2010 ftcaltechdiss https://doi.org/10.7907/N1MW-8Q84 2022-02-09T19:01:23Z The ocean is a major component of global heat transport and represents a large exchangeable reservoir of CO₂. The importance of these effects on climate can be quantified with records of ocean temperature, chemistry and dynamics spanning past climate change. One approach to reconstruct past ocean conditions relies on the chemical composition of CaCO₃ skeletons from coral. Despite the utility of these geochemical proxies, several lines of evidence suggest that biomineralization, the process corals use to build their skeletons, also influences composition, complicating the interpretation of past records. Coral grown under constant environmental conditions, either collected from the deep-sea or cultured in the laboratory, are used to quantify and spatially map the effects of biomineralization on skeletal composition. In modern deep-sea coral, Mg/Ca increases with decreasing Sr/Ca in most the skeleton, consistent with closed-system (Rayleigh) precipitation. Results also show composition strongly follows skeletal architecture. Centers of calcification (COCs) are small regions of disorganized crystals thought to be the initial stage of skeletal extension. Unlike the rest of the skeleton, Mg/Ca ratios vary more than two fold within the COCs while Sr/Ca is near constant. Our data provide new constraints on a number of possible mechanisms for this effect. In a complementary set of experiments the nanoSIMS, a new instrument capable of accurate sub-micron compositional analysis, is applied to adult cultured surface coral (1) mapping the pattern of metal ion incorporation in new growth and showing that the calcifying fluid is likely in direct exchange with seawater; and (2) testing the sensitivity of Me/Ca ratios to aragonite saturation Ω. Despite a large range of Ω and calcification rates, the average Sr/Ca of nanoSIMS spot measurements in cultured coral are within 1.2% (2 sigma std. dev. of the 5 means). These data suggest that temperature is a more significant control on Sr/Ca than aragonite saturation between Ω = 2.5--5. Within the framework of a closed-system (Rayleigh) model for biomineralization the results constrain explanations for the sensitivity of coral calcification rates to ocean acidification, improving our understanding of how anthropogenic CO₂ will impact coral reefs. Thesis Ocean acidification CaltechTHESIS (California Institute of Technology
institution Open Polar
collection CaltechTHESIS (California Institute of Technology
op_collection_id ftcaltechdiss
language English
description The ocean is a major component of global heat transport and represents a large exchangeable reservoir of CO₂. The importance of these effects on climate can be quantified with records of ocean temperature, chemistry and dynamics spanning past climate change. One approach to reconstruct past ocean conditions relies on the chemical composition of CaCO₃ skeletons from coral. Despite the utility of these geochemical proxies, several lines of evidence suggest that biomineralization, the process corals use to build their skeletons, also influences composition, complicating the interpretation of past records. Coral grown under constant environmental conditions, either collected from the deep-sea or cultured in the laboratory, are used to quantify and spatially map the effects of biomineralization on skeletal composition. In modern deep-sea coral, Mg/Ca increases with decreasing Sr/Ca in most the skeleton, consistent with closed-system (Rayleigh) precipitation. Results also show composition strongly follows skeletal architecture. Centers of calcification (COCs) are small regions of disorganized crystals thought to be the initial stage of skeletal extension. Unlike the rest of the skeleton, Mg/Ca ratios vary more than two fold within the COCs while Sr/Ca is near constant. Our data provide new constraints on a number of possible mechanisms for this effect. In a complementary set of experiments the nanoSIMS, a new instrument capable of accurate sub-micron compositional analysis, is applied to adult cultured surface coral (1) mapping the pattern of metal ion incorporation in new growth and showing that the calcifying fluid is likely in direct exchange with seawater; and (2) testing the sensitivity of Me/Ca ratios to aragonite saturation Ω. Despite a large range of Ω and calcification rates, the average Sr/Ca of nanoSIMS spot measurements in cultured coral are within 1.2% (2 sigma std. dev. of the 5 means). These data suggest that temperature is a more significant control on Sr/Ca than aragonite saturation between Ω = 2.5--5. Within the framework of a closed-system (Rayleigh) model for biomineralization the results constrain explanations for the sensitivity of coral calcification rates to ocean acidification, improving our understanding of how anthropogenic CO₂ will impact coral reefs.
format Thesis
author Gagnon, Alexander C.
spellingShingle Gagnon, Alexander C.
Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
author_facet Gagnon, Alexander C.
author_sort Gagnon, Alexander C.
title Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
title_short Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
title_full Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
title_fullStr Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
title_full_unstemmed Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals
title_sort geochemical mechanisms of biomineralization from analysis of deep-sea and laboratory cultured corals
publishDate 2010
url https://thesis.library.caltech.edu/5790/
https://thesis.library.caltech.edu/5790/2/Gagnon_thesis_09_CIT_revised.pdf
https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148
genre Ocean acidification
genre_facet Ocean acidification
op_relation https://thesis.library.caltech.edu/5790/2/Gagnon_thesis_09_CIT_revised.pdf
Gagnon, Alexander C. (2010) Geochemical Mechanisms of Biomineralization from Analysis of Deep-Sea and Laboratory Cultured Corals. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/N1MW-8Q84. https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148 <https://resolver.caltech.edu/CaltechTHESIS:05102010-102555148>
op_rights other
op_doi https://doi.org/10.7907/N1MW-8Q84
_version_ 1766159442258165760

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