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10 results on '"Charlotte L. O’Brien"'

2. The enigma of Oligocene climate and global surface temperature evolution

Author

Matthew Huber, Pincelli M. Hull, Charlotte L O'Brien, James R Super, Leanne E. Elder, Ellen Thomas, and Mark Pagani

Subjects
geography, Multidisciplinary, geography.geographical_feature_category, Eocene–Oligocene, Antarctic ice sheet, TEX86, Deep sea, proxy reconstructions, Sea surface temperature, Oceanography, Earth, Atmospheric, and Planetary Sciences, climate models, Physical Sciences, Climate sensitivity, Climate model, sea surface temperatures, Ice sheet, Cenozoic, Geology
Abstract

Significance During the Eocene, high-latitude regions were much warmer than today and substantial polar ice sheets were lacking. Indeed, the initiation of significant polar ice sheets near the end of the Eocene has been closely linked to global cooling. Here, we examine the relationship between global temperatures and continental-scale polar ice sheets following the establishment of ice sheets on Antarctica ∼34 million years ago, using records of surface temperatures from around the world. We find that high-latitude temperatures were almost as warm after the initiation of Antarctic glaciation as before, challenging our basic understanding of how climate works, and of the development of climate and ice volume through time., Falling atmospheric CO2 levels led to cooling through the Eocene and the expansion of Antarctic ice sheets close to their modern size near the beginning of the Oligocene, a period of poorly documented climate. Here, we present a record of climate evolution across the entire Oligocene (33.9 to 23.0 Ma) based on TEX86 sea surface temperature (SST) estimates from southwestern Atlantic Deep Sea Drilling Project Site 516 (paleolatitude ∼36°S) and western equatorial Atlantic Ocean Drilling Project Site 929 (paleolatitude ∼0°), combined with a compilation of existing SST records and climate modeling. In this relatively low CO2 Oligocene world (∼300 to 700 ppm), warm climates similar to those of the late Eocene continued with only brief interruptions, while the Antarctic ice sheet waxed and waned. SSTs are spatially heterogenous, but generally support late Oligocene warming coincident with declining atmospheric CO2. This Oligocene warmth, especially at high latitudes, belies a simple relationship between climate and atmospheric CO2 and/or ocean gateways, and is only partially explained by current climate models. Although the dominant climate drivers of this enigmatic Oligocene world remain unclear, our results help fill a gap in understanding past Cenozoic climates and the way long-term climate sensitivity responded to varying background climate states.

Published
2020

5. Palaeogeographic controls on climate and proxy interpretation

Author

Charlotte L O'Brien, Stuart A. Robinson, Neil Wrobel, Gavin L. Foster, Alexander Farnsworth, Daniel J. Lunt, Paul J. Markwick, Richard D. Pancost, and Claire Loptson

Subjects
lcsh:GE1-350, Global and Planetary Change, Solar constant, 010504 meteorology & atmospheric sciences, lcsh:Environmental protection, Stratigraphy, Ocean current, Paleontology, Climate change, Global change, Orography, 010502 geochemistry & geophysics, 01 natural sciences, Proxy (climate), Carbon cycle, lcsh:Environmental pollution, Climatology, lcsh:TD172-193.5, Polar amplification, lcsh:TD169-171.8, lcsh:Environmental sciences, Geology, 0105 earth and related environmental sciences
Abstract

During the period from approximately 150 to 35 million years ago, the Cretaceous–Paleocene–Eocene (CPE), the Earth was in a “greenhouse” state with little or no ice at either pole. It was also a period of considerable global change, from the warmest periods of the mid-Cretaceous, to the threshold of icehouse conditions at the end of the Eocene. However, the relative contribution of palaeogeographic change, solar change, and carbon cycle change to these climatic variations is unknown. Here, making use of recent advances in computing power, and a set of unique palaeogeographic maps, we carry out an ensemble of 19 General Circulation Model simulations covering this period, one simulation per stratigraphic stage. By maintaining atmospheric CO2 concentration constant across the simulations, we are able to identify the contribution from palaeogeographic and solar forcing to global change across the CPE, and explore the underlying mechanisms. We find that global mean surface temperature is remarkably constant across the simulations, resulting from a cancellation of opposing trends from solar and palaeogeographic change. However, there are significant modelled variations on a regional scale. The stratigraphic stage–stage transitions which exhibit greatest climatic change are associated with transitions in the mode of ocean circulation, themselves often associated with changes in ocean gateways, and amplified by feedbacks related to emissivity and planetary albedo. We also find some control on global mean temperature from continental area and global mean orography. Our results have important implications for the interpretation of single-site palaeo proxy records. In particular, our results allow the non-CO2 (i.e. palaeogeographic and solar constant) components of proxy records to be removed, leaving a more global component associated with carbon cycle change. This “adjustment factor” is used to adjust sea surface temperatures, as the deep ocean is not fully equilibrated in the model. The adjustment factor is illustrated for seven key sites in the CPE, and applied to proxy data from Falkland Plateau, and we provide data so that similar adjustments can be made to any site and for any time period within the CPE. Ultimately, this will enable isolation of the CO2-forced climate signal to be extracted from multiple proxy records from around the globe, allowing an evaluation of the regional signals and extent of polar amplification in response to CO2 changes during the CPE. Finally, regions where the adjustment factor is constant throughout the CPE could indicate places where future proxies could be targeted in order to reconstruct the purest CO2-induced temperature change, where the complicating contributions of other processes are minimised. Therefore, combined with other considerations, this work could provide useful information for supporting targets for drilling localities and outcrop studies.

Published
2016
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8. High sea surface temperatures in tropical warm pools during the Pliocene

Author

Charlotte L O'Brien, Richard Abell, Richard D. Pancost, Gavin L. Foster, James W. B. Rae, Miguel A. Martínez-Botí, University of St Andrews. School of Earth & Environmental Sciences, University of St Andrews. St Andrews Isotope Geochemistry, and University of St Andrews. Earth and Environmental Sciences

Subjects
GC, Sea surface temperature, Oceanography, GE, Climatology, Period (geology), General Earth and Planetary Sciences, Biogeochemistry, GC Oceanography, BDC, Geology, R2C, GE Environmental Sciences
Abstract

This work was supported by a NERC studentship awarded to C.L.O’B. and a NERC standard grant NE/H006273/1 awarded to R.D.P. (Principal Investigator) and G.L.F. (Co-Investigator). R.D.P. also acknowledges the Royal Society Wolfson Research Merit Award. M.A.M-B. gratefully acknowledges the support of the European Community through a Marie Curie Intra-European Fellowship for Career Development. The western warm pools of the Atlantic and Pacific oceans are a critical source of heat and moisture for the tropical climate system. Over the past five million years, global mean temperatures have cooled by 3–4 °C. Yet, present reconstructions of sea surface temperatures indicate that temperature in the warm pools has remained stable during this time. This stability has been used to suggest that tropical sea surface temperatures are controlled by a thermostat-like mechanism that maintained consistent temperatures. Here we reconstruct sea surface temperatures in the South China Sea, Caribbean Sea and western equatorial Pacific Ocean for the past five million years, using a combination of the Mg/Ca-, TEX86H- and Uk'37- surface-temperature proxies. Our data indicate that during the period of Pliocene warmth from about 5 to 2.6 million years ago, the western Pacific and western Atlantic warm pools were about 2 °C warmer than today. We suggest that the apparent lack of warmth seen in the previous reconstructions was an artefact of low seawater Mg/Ca ratios in the Pliocene oceans. Taking this bias into account, our data indicate that tropical sea surface temperatures did change in conjunction with global mean temperatures. We therefore conclude that the temperature of the warm pools of the equatorial oceans during the Pliocene was not limited by a thermostat-like mechanism. Postprint

Published
2014

9. A cool temperate climate on the Antarctic Peninsula during the latest Cretaceous and early Paleogene

Author

J. Alistair Crame, Jon R. Ineson, Stuart A. Robinson, David B. Kemp, Rowan J. Whittle, Jane E. Francis, Vanessa C. Bowman, and Charlotte L O'Brien

Subjects
geography, geography.geographical_feature_category, Geology, Ecological succession, Proxy (climate), Cretaceous, Paleothermometer, Oceanography, 13. Climate action, Peninsula, Temperate climate, Sedimentary rock, Paleogene
Abstract

Constraining past fl uctuations in global temperatures is central to our understanding of the Earth’s climatic evolution. Marine proxies dominate records of past temperature reconstructions, whereas our understanding of continental climate is relatively poor, particularly in high-latitude areas such as Antarctica. The recently developed MBT/CBT (methylation index of branched tetraethers/ cyclization ratio of branched tetraethers) paleothermometer offers an opportunity to quantify ancient continental climates at temporal resolutions typically not afforded by terrestrial macrofl oral proxies. Here, we have extended the application of the MBT/CBT proxy into the Cretaceous by presenting paleotemperatures through an expanded sedimentary succession from Seymour Island, Antarctica, spanning the latest Maastrichtian and Paleocene. Our data indicate the existence of a relatively stable, persistently cool temperate climate on the Antarctic Peninsula across the Cretaceous-Paleogene boundary. These new data help elucidate the climatic evolution of Antarctica across one of the Earth’s most pronounced biotic reorganizations at the Cretaceous-Paleogene boundary, prior to major icesheet development in the late Paleogene. Our work emphasizes the likely existence of temporal and/or spatial heterogeneities in climate of the southern high latitudes during the early Paleogene.

Published
2014

10. Reply to 'Pliocene warmth and gradients'

Author

Gavin L. Foster, James W. B. Rae, Richard D. Pancost, and Charlotte L O'Brien

Subjects
Oceanography, Climatology, Period (geology), General Earth and Planetary Sciences, Western Hemisphere Warm Pool, Holocene, Geology
Abstract

Brierley et al.1 question our findings of elevated temperatures in the tropical warm pools during the Pliocene2. Focusing specifically on the mid-Pliocene warm period (about 3.3 to 3 million years ago), as framed by Brierley et al., we continue to find evidence for warmer than Holocene temperatures in the western Pacific warm pool in good agreement with PlioMIP simulations, especially in light of new pCO2 reconstructions3.

Published
2015
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