Your search keyword '"Beaufort L"' showing total 4 results

1. Sensitivity of coccolithophores to carbonate chemistry and ocean acidification

Author

Beaufort, L., Probert, I., de Garidel-Thoron, T., Bendif, E.M., Ruiz-Pino, D., Metzl, N., Goyet, C., Buchet, N., Coupel, P., Grelaud, M., Rost, B., Rickaby, R.E.M., and de Vargas, C.

Subjects

Water acidification -- Environmental aspects, Carbonates -- Chemical properties -- Environmental aspects, Coccolithophorids -- Chemical properties, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

About one-third of the carbon dioxide (C[O.sub.2]) released into the atmosphere as a result of human activity has been absorbed by the oceans (1), where it partitions into the constituent ions of carbonic acid. This leads to ocean acidification, one of the major threats to marine ecosystems (2) and particularly to calcifying organisms such as corals (3,4), foraminifera (5-7) and coccolithophores (8). Coccolithophores are abundant phytoplankton that are responsible for a large part of modern oceanic carbonate production. Culture experiments investigating the physiological response of coccolithophore calcification to increased C[O.sub.2] have yielded contradictory results between and even within species (8-11). Here we quantified the calcite mass of dominant coccolithophores in the present ocean and over the past forty thousand years, and found a marked pattern of decreasing calcification with increasing partial pressure of C[O.sub.2] and concomitant decreasing concentrations of C[O.sub.3.sup.2-]. Our analyses revealed that differentially calcified species and morphotypes are distributed in the ocean according to carbonate chemistry. A substantial impact on the marine carbon cycle might be expected upon extrapolation of this correlation to predicted ocean acidification in the future. However, our discovery of a heavily calcified Emiliania huxleyi morphotype in modern waters with low pH highlights the complexity of assemblage-level responses to environmental forcing factors., To assess the influence of the environment on coccolithophore calcification, we investigated 180 surface-water and 555 sediment-core samples encompassing a wide spectrum of present and past oceanic conditions (Fig. 1). [...]

Published

2011

2. Cyclic evolution of phytoplankton forced by changes in tropical seasonality.

Author

Beaufort L, Bolton CT, Sarr AC, Suchéras-Marx B, Rosenthal Y, Donnadieu Y, Barbarin N, Bova S, Cornuault P, Gally Y, Gray E, Mazur JC, and Tetard M

Subjects

Carbon Cycle, Ecosystem, Fossils, Geologic Sediments, History, Ancient, Indian Ocean, Pacific Ocean, Time Factors, Biological Evolution, Climate Change statistics & numerical data, Phytoplankton metabolism, Seasons, Tropical Climate

Abstract

Although the role of Earth's orbital variations in driving global climate cycles has long been recognized, their effect on evolution is hitherto unknown. The fossil remains of coccolithophores, a key calcifying phytoplankton group, enable a detailed assessment of the effect of cyclic orbital-scale climate changes on evolution because of their abundance in marine sediments and the preservation of their morphological adaptation to the changing environment 1,2 . Evolutionary genetic analyses have linked broad changes in Pleistocene fossil coccolith morphology to species radiation events 3 . Here, using high-resolution coccolith data, we show that during the last 2.8 million years the morphological evolution of coccolithophores was forced by Earth's orbital eccentricity with rhythms of around 100,000 years and 405,000 years-a distinct spectral signature to that of coeval global climate cycles 4 . Simulations with an Earth System Model 5 coupled with an ocean biogeochemical model 6 show a strong eccentricity modulation of the seasonal cycle, which we suggest directly affects the diversity of ecological niches that occur over the annual cycle in the tropical ocean. Reduced seasonality in surface ocean conditions favours species with mid-size coccoliths, increasing coccolith carbonate export and burial; whereas enhanced seasonality favours a larger range of coccolith sizes and reduced carbonate export. We posit that eccentricity pacing of phytoplankton evolution contributed to the strong 405,000-year cyclicity that is seen in global carbon cycle records., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

3. Moisture transport across Central America as a positive feedback on abrupt climatic changes.

Author

Leduc G, Vidal L, Tachikawa K, Rostek F, Sonzogni C, Beaufort L, and Bard E

Subjects

Animals, Atlantic Ocean, Central America, Oxygen Isotopes, Pacific Ocean, Rain, Seawater chemistry, Sodium Chloride analysis, Temperature, Greenhouse Effect, Humidity, Water Movements

Abstract

Moisture transport from the Atlantic to the Pacific ocean across Central America leads to relatively high salinities in the North Atlantic Ocean and contributes to the formation of North Atlantic Deep Water. This deep water formation varied strongly between Dansgaard/Oeschger interstadials and Heinrich events-millennial-scale abrupt warm and cold events, respectively, during the last glacial period. Increases in the moisture transport across Central America have been proposed to coincide with northerly shifts of the Intertropical Convergence Zone and with Dansgaard/Oeschger interstadials, with opposite changes for Heinrich events. Here we reconstruct sea surface salinities in the eastern equatorial Pacific Ocean over the past 90,000 years by comparing palaeotemperature estimates from alkenones and Mg/Ca ratios with foraminiferal oxygen isotope ratios that vary with both temperature and salinity. We detect millennial-scale fluctuations of sea surface salinities in the eastern equatorial Pacific Ocean of up to two to four practical salinity units. High salinities are associated with the southward migration of the tropical Atlantic Intertropical Convergence Zone, coinciding with Heinrich events and with Greenland stadials. The amplitudes of these salinity variations are significantly larger on the Pacific side of the Panama isthmus, as inferred from a comparison of our data with a palaeoclimate record from the Caribbean basin. We conclude that millennial-scale fluctuations of moisture transport constitute an important feedback mechanism for abrupt climate changes, modulating the North Atlantic freshwater budget and hence North Atlantic Deep Water formation.

Published

2007

4. Stable sea surface temperatures in the western Pacific warm pool over the past 1.75 million years.

Author

de Garidel-Thoron T, Rosenthal Y, Bassinot F, and Beaufort L

Subjects

Atmosphere chemistry, Carbon Dioxide analysis, Ice Cover, Pacific Ocean, Plankton chemistry, Time Factors, Climate, Seawater chemistry, Seawater microbiology, Temperature

Abstract

About 850,000 years ago, the period of the glacial cycles changed from 41,000 to 100,000 years. This mid-Pleistocene climate transition has been attributed to global cooling, possibly caused by a decrease in atmospheric carbon dioxide concentrations. However, evidence for such cooling is currently restricted to the cool upwelling regions in the eastern equatorial oceans, although the tropical warm pools on the western side of the ocean basins are particularly sensitive to changes in radiative forcing. Here we present high-resolution records of sea surface temperatures spanning the past 1.75 million years, obtained from oxygen isotopes and Mg/Ca ratios in planktonic foraminifera from the western Pacific warm pool. In contrast with the eastern equatorial regions, sea surface temperatures in the western Pacific warm pool are relatively stable throughout the Pleistocene epoch, implying little long-term change in the tropical net radiation budget. Our results challenge the hypothesis of a gradual decrease in atmospheric carbon dioxide concentrations as a dominant trigger of the longer glacial cycles since 850,000 years ago. Instead, we infer that the temperature contrast across the equatorial Pacific Ocean increased, which might have had a significant influence on the mid-Pleistocene climate transition.

Published

2005