Your search keyword '"Rickaby RE"' showing total 4 results

1. The origin of carbon isotope vital effects in coccolith calcite.

Author

McClelland HL, Bruggeman J, Hermoso M, and Rickaby RE

Abstract

Calcite microfossils are widely used to study climate and oceanography in Earth's geological past. Coccoliths, readily preserved calcite plates produced by a group of single-celled surface-ocean dwelling algae called coccolithophores, have formed a significant fraction of marine sediments since the Late Triassic. However, unlike the shells of foraminifera, their zooplankton counterparts, coccoliths remain underused in palaeo-reconstructions. Precipitated in an intracellular chemical and isotopic microenvironment, coccolith calcite exhibits large and enigmatic departures from the isotopic composition of abiogenic calcite, known as vital effects. Here we show that the calcification to carbon fixation ratio determines whether coccolith calcite is isotopically heavier or lighter than abiogenic calcite, and that the size of the deviation is determined by the degree of carbon utilization. We discuss the theoretical potential for, and current limitations of, coccolith-based CO 2 paleobarometry, that may eventually facilitate use of the ubiquitous and geologically extensive sedimentary archive.

Published

2017

2. The uronic acid content of coccolith-associated polysaccharides provides insight into coccolithogenesis and past climate.

Author

Lee RB, Mavridou DA, Papadakos G, McClelland HL, and Rickaby RE

Subjects

Adaptation, Physiological, Calcification, Physiologic, Calcium Carbonate history, Calcium Carbonate metabolism, Carbon history, Carbon metabolism, Carbon Dioxide chemistry, Carbon Dioxide history, Carbon Dioxide metabolism, Crystallization, Fossils history, Haptophyta classification, Haptophyta metabolism, History, Ancient, Paleontology, Phytoplankton classification, Phytoplankton metabolism, Polysaccharides history, Polysaccharides metabolism, Species Specificity, Uronic Acids history, Uronic Acids metabolism, Calcium Carbonate chemistry, Carbon chemistry, Haptophyta chemistry, Phytoplankton chemistry, Polysaccharides chemistry, Uronic Acids chemistry

Abstract

Unicellular phytoplanktonic algae (coccolithophores) are among the most prolific producers of calcium carbonate on the planet, with a production of ∼10 26 coccoliths per year. During their lith formation, coccolithophores mainly employ coccolith-associated polysaccharides (CAPs) for the regulation of crystal nucleation and growth. These macromolecules interact with the intracellular calcifying compartment (coccolith vesicle) through the charged carboxyl groups of their uronic acid residues. Here we report the isolation of CAPs from modern day coccolithophores and their prehistoric predecessors and we demonstrate that their uronic acid content (UAC) offers a species-specific signature. We also show that there is a correlation between the UAC of CAPs and the internal saturation state of the coccolith vesicle that, for most geologically abundant species, is inextricably linked to carbon availability. These findings suggest that the UAC of CAPs reports on the adaptation of coccolithogenesis to environmental changes and can be used for the estimation of past CO 2 concentrations.

Published

2016

3. Erratum: Oxygen depletion recorded in upper waters of the glacial Southern Ocean.

Author

Lu Z, Hoogakker BA, Hillenbrand CD, Zhou X, Thomas E, Gutchness KM, Lu W, Jones L, and Rickaby RE

Published

2016

4. Oxygen depletion recorded in upper waters of the glacial Southern Ocean.

Author

Lu Z, Hoogakker BA, Hillenbrand CD, Zhou X, Thomas E, Gutchess KM, Lu W, Jones L, and Rickaby RE

Abstract

Oxygen depletion in the upper ocean is commonly associated with poor ventilation and storage of respired carbon, potentially linked to atmospheric CO2 levels. Iodine to calcium ratios (I/Ca) in recent planktonic foraminifera suggest that values less than ∼2.5 μmol mol(-1) indicate the presence of O2-depleted water. Here we apply this proxy to estimate past dissolved oxygen concentrations in the near surface waters of the currently well-oxygenated Southern Ocean, which played a critical role in carbon sequestration during glacial times. A down-core planktonic I/Ca record from south of the Antarctic Polar Front (APF) suggests that minimum O2 concentrations in the upper ocean fell below 70 μmol kg(-1) during the last two glacial periods, indicating persistent glacial O2 depletion at the heart of the carbon engine of the Earth's climate system. These new estimates of past ocean oxygenation variability may assist in resolving mechanisms responsible for the much-debated ice-age atmospheric CO2 decline.

Published

2016