Exploring the carbon isotopic ratio and chemistry of coccoliths and coccolith associated polysaccharides as a proxy for CO2

<p>Our planet is habitable, in part, due to the carbon dioxide (CO2) that resides in our at- mosphere. Whilst the presence of CO₂ ensures that ambient surface temperatures remain above freezing, additional inputs of CO2 drive global temperatures higher. The long-term increase in temperature associated with an increase in the mixing ratio of CO2₂ in the at- mosphere (pCO₂) is, however, not certain. In order to understand how much our planet’s temperature rises given an increase pCO₂, we look to the sedimentary record to reconstruct coupled changes in past temperature and pCO₂. Yet, reconstructing pCO2 is marred by inaccurate proxies, which often require numerous assumptions and only provide snapshots of past change. Recent work has linked chemical signals recorded in coccolithophores, unicellular phytoplankton, to changes in the CO₂ concentration of seawater ([CO_2(aq)), which reflects pCO2 in certain ocean settings. Such signals manifest in calcium carbonate plates, know as coccoliths, that coccolithophores produce and their associated polysac- charides, which assist with coccolith calcification. This thesis set out to investigate the use of coccoliths and coccolith associated polysaccharides (CAPs) as a proxy for pCO₂. I first invert an existing coccolithophore cellular carbon isotopic flux model to reconstruct pCO2 given novel carbon isotopic data from size separated coccoliths dating to the Eocene period (56-34 million years ago). This work takes advantage of the understanding that the external concentration of CO₂ in seawater, in part, controls the carbon isotopic composition of coccolith calcite. I find that pCO₂ declined over the Eocene period with a corresponding shift to less calcified coccolithophore species. Second, I recalibrate an existing cellular carbon isotopic flux model with novel isotopic data measured from culture experiments to derive insight into modern day species carbon acquisition strategies. I find that two modern coccolithophore species, Gephyrocapsa Oceanica and Coccolithus pelagicus, have differing responses to CO_2(aq) limitation. Whilst G. Oceanica likely upregulates HCO⁻₃ transporters under carbon limitation, Coccolithus pelagicus utilises HCO⁻₃ over all carbonate parameter space. Finally, I investigate the chemical and isotopic response of CAPs trapped within coccoliths from both culture and the sedimentary record to changes in CO_2(aq). I find that both the monosaccharide composition and carbon isotopic ratio of CAPs vary over CO_2(aq) space. Whilst species specific behaviour is apparent, collective changes observed across species point towards the potential development of a CAP based pCO₂ proxy. Taken together the work presented in this thesis lays the foundation for a suite of novel pCO₂ proxies that may, with supplementary work, reconstruct pCO₂ back to the Triassic period when coccoliths first appeared in the fossil record.</p>