The Response of Marine Carbonate Chemistry to Rapid Carbon Injection During the Paleocene-eocene Thermal Maximum
The Response of Marine Carbonate Chemistry to Rapid Carbon Injection During the Paleocene-eocene Thermal Maximum

Author:

Publisher:

Published: 2015

Total Pages: 167

ISBN-13: 9781321676150

DOWNLOAD EBOOK

This dissertation reconstructs the response of marine carbonate chemistry to rapid carbon injection during the Paleocene-Eocene Thermal Maximum (PETM). Chapter 1 uses boron-based proxies to reconstruct ocean acidification during the PETM for the first time, concluding that surface seawater pH declined by ∼0.3 units at the onset of the event, and remained acidified for at least 70 thousand years before recovering in step with temperature and the carbon isotopic signature of the PETM. Chapter 2 describes a new sedimentary record of the PETM from the deep North Atlantic which provides the first evidence for a hypothesized "overshoot" of carbonate saturation in the aftermath of the PETM in response to long-term weathering feedbacks on climate. Stable isotope records from that section demonstrate that this overshoot occurred during the recovery of the PETM, ∼70 thousand years after its onset, which provides novel constraints on the evolution of the carbonate compensation depth over the event. Finally, Chapter 3 uses these new (and previous) records to constrain carbon cycle model simulations of the PETM. Consistent runs require both a large initial release as well as a protracted release over tens of thousands of years (possibly representing a slow positive feedback to warming) and the removal of isotopically light carbon to accelerate the PETM recovery, likely representing organic carbon burial. No consistent scenarios feature under-saturated conditions in the surface ocean during the PETM, consistent with the lack of calcifier extinctions during the event. Comparison of the most consistent PETM scenarios with forecasts of anthropogenic carbon emissions demonstrate that carbonate chemistry change during the PETM was less severe and far more gradual than what might be expected in coming centuries.

Fluvial Response to the Paleocene-Eocene Thermal Maximum in Western North America
Fluvial Response to the Paleocene-Eocene Thermal Maximum in Western North America

Author: Brady Z. Foreman

Publisher:

Published: 2013

Total Pages: 506

ISBN-13: 9781303049613

DOWNLOAD EBOOK

The Paleocene-Eocene boundary ca. 56 million years ago is characterized by an extreme global warming event, known as the Paleocene-Eocene Thermal Maximum (PETM). The event is linked to the massive exogenic release of isotopically-light carbon into Earth's oceans and atmosphere, and is recognizable in the geologic record by an abrupt negative carbon isotope excursion in both organic and inorganic proxy records for duration of approximately 200,000 years. Previous studies indicate the PETM instigated massive changes in ocean and atmospheric circulation, which perturbed both terrestrial and marine environmental conditions and biotic systems. This study exploits the PETM to examine the effects of abrupt climate change on fluvial stratigraphy. The negative carbon isotope excursion associated with the PETM allows the timing and duration of the climate change to be identified independent of lithostratigraphic markers. Local climate shifts are constrained using circulation models, soil geochemistry, and paleobotanical records. Two areas are studied in detail, the Piceance Creek Basin of Colorado and the northern Bighorn Basin of Wyoming. In both areas anomalously thick and laterally persistent fluvial sand-bodies correlate with the PETM interval. In the Piceance Creek Basin the shift in fluvial deposition directly correlates with the onset of the PETM and persists beyond the carbon isotope excursion, whereas in the northern Bighorn Basin the shift appears to lag the isotope excursion by 10-20 thousand years and ends prior to the return to background climatic conditions. In the Piceance Creek Basin the change in sand-body geometry is associated with a shift to deeper paleoflow depths, wider channels, greater preservation of upper flow regime structures, prevalent crevasse splay deposits, and poorer drained floodplain soils. In contrast, within the Bighorn Basin there are no such changes and, apart from greater amalgamation, fluvial deposition appears to be largely unaffected by the PETM. When combined with other PETM terrestrial localities, the records demonstrate the PETM had substantial, but spatially diverse effects on basin-scale grain-size partitioning, discharge regimes, and river-floodplain dynamics. Aspects of the responses in the various basins are reminiscent of those predicted by two-dimensional basin-fill models, however, key differences highlight the role non-linearities, feedback loops, relaxation times, basin geometry, seasonality of precipitation, and vegetation factors play in determining large-scale depositional patterns. Consequently, it is concluded that short-term climatic events such as the PETM hold the potential to strongly alter basin sedimentation patterns, but that the sedimentologic-recorded climatic signal cannot be used to directly reconstruct paleoclimatic conditions. Instead a more appropriate approach is advocated that uses fluvial stratigraphy in concert with geochemical and other proxies to iteratively produce a more robust image of paleolandscape dynamics.

The Planktonic Foraminiferal Response to the Paleocene Eocene Thermal Maximum on the Atlantic Coastal Plain
The Planktonic Foraminiferal Response to the Paleocene Eocene Thermal Maximum on the Atlantic Coastal Plain

Author: Caitlin Livsey

Publisher:

Published: 2015

Total Pages:

ISBN-13:

DOWNLOAD EBOOK

Cores on the Atlantic Coastal Plain contain an expanded record of the onset of the Paleocene Eocene Thermal Maximum (PETM), an abrupt global warming event occurring 55 mya. Though a seemingly well-studied event, details about what exactly occurred during the PETM are still lacking due to differential local effects, absence of precise time resolution, and considerable dissolution of deep sea carbonates at the onset of the event. Here we present high-resolution planktonic foraminiferal assemblage data from cores from Maryland and New Jersey that show significant changes in surface ocean habitats immediately before and during the onset of the event. Assemblages immediately below the PETM show evidence for environmental stress including oligotrophy, while marked changes in assemblages at the onset of the event reflect an increase in stratification. An anomalously high abundance of the stress indicating triserial/biserial planktonic foraminifera in the late Paleocene support the increase in environmental stress directly prior to the event on the coastal plain. We observe Acarinina sibaiyaensis, a species previously thought to have originated during the PETM, below the event at both sites. The appearance of A. sibaiyaensis prior to the PETM in the Atlantic Coastal Plain suggests that it evolved on the shelf in response to oligotrophy and tracked these conditions to the open ocean during the event. Planktonic foraminifera diversified on the shelf during the PETM likely due to a combination of sea level rise, warming of the coastal waters, and consequent increased stratification, which provided new habitats. We present the occurrence of variant morphologies of several planktonic foraminifera near the peak of the carbon isotope excursion at Bass River, which may signal the response of the assemblage to environmental perturbation. These high-resolution records of planktonic foraminifera from before and during the onset of the PETM offer insights into how the local environment shifted across the event, and what that meant for the evolution of Acarinina sibaiyaensis.

Understanding Earth's Deep Past
Understanding Earth's Deep Past

Author: National Research Council

Publisher: National Academies Press

Published: 2011-08-02

Total Pages: 153

ISBN-13: 0309209196

DOWNLOAD EBOOK

There is little dispute within the scientific community that humans are changing Earth's climate on a decadal to century time-scale. By the end of this century, without a reduction in emissions, atmospheric CO2 is projected to increase to levels that Earth has not experienced for more than 30 million years. As greenhouse gas emissions propel Earth toward a warmer climate state, an improved understanding of climate dynamics in warm environments is needed to inform public policy decisions. In Understanding Earth's Deep Past, the National Research Council reports that rocks and sediments that are millions of years old hold clues to how the Earth's future climate would respond in an environment with high levels of atmospheric greenhouse gases. Understanding Earth's Deep Past provides an assessment of both the demonstrated and underdeveloped potential of the deep-time geologic record to inform us about the dynamics of the global climate system. The report describes past climate changes, and discusses potential impacts of high levels of atmospheric greenhouse gases on regional climates, water resources, marine and terrestrial ecosystems, and the cycling of life-sustaining elements. While revealing gaps in scientific knowledge of past climate states, the report highlights a range of high priority research issues with potential for major advances in the scientific understanding of climate processes. This proposed integrated, deep-time climate research program would study how climate responded over Earth's different climate states, examine how climate responds to increased atmospheric carbon dioxide and other greenhouse gases, and clarify the processes that lead to anomalously warm polar and tropical regions and the impact on marine and terrestrial life. In addition to outlining a research agenda, Understanding Earth's Deep Past proposes an implementation strategy that will be an invaluable resource to decision-makers in the field, as well as the research community, advocacy organizations, government agencies, and college professors and students.

Large Igneous Provinces
Large Igneous Provinces

Author: Richard E. Ernst

Publisher: Cambridge University Press

Published: 2014-09-25

Total Pages: 667

ISBN-13: 1316060519

DOWNLOAD EBOOK

Large igneous provinces (LIPs) are intraplate magmatic events, involving volumes of mainly mafic magma upwards of 100,000 km3, and often above 1 million km3. They are linked to continental break-up, global environmental catastrophes, regional uplift and a variety of ore deposit types. In this up-to-date, fascinating book, leading expert Richard E. Ernst explores all aspects of LIPs, beginning by introducing their definition and essential characteristics. Topics covered include continental and oceanic LIPs; their origins, structures, and geochemistry; geological and environmental effects; association with silicic, carbonatite and kimberlite magmatism; and analogues of LIPs in the Archean, and on other planets. The book concludes with an assessment of LIPs' influence on natural resources such as mineral deposits, petroleum and aquifers. This is a one-stop resource for researchers and graduate students in a wide range of disciplines, including tectonics, igneous petrology, geochemistry, geophysics, Earth history, and planetary geology, and for mining industry professionals.

The Vegetation of Antarctica through Geological Time
The Vegetation of Antarctica through Geological Time

Author: David J. Cantrill

Publisher: Cambridge University Press

Published: 2012-11-22

Total Pages: 489

ISBN-13: 113956028X

DOWNLOAD EBOOK

The fossil history of plant life in Antarctica is central to our understanding of the evolution of vegetation through geological time and also plays a key role in reconstructing past configurations of the continents and associated climatic conditions. This book provides the only detailed overview of the development of Antarctic vegetation from the Devonian period to the present day, presenting Earth scientists with valuable insights into the break up of the ancient supercontinent of Gondwana. Details of specific floras and ecosystems are provided within the context of changing geological, geographical and environmental conditions, alongside comparisons with contemporaneous and modern ecosystems. The authors demonstrate how palaeobotany contributes to our understanding of the paleoenvironmental changes in the southern hemisphere during this period of Earth history. The book is a complete and up-to-date reference for researchers and students in Antarctic paleobotany and terrestrial paleoecology.

Tracking the Paleocene-Eocene Thermal Maximum in the North Atlantic
Tracking the Paleocene-Eocene Thermal Maximum in the North Atlantic

Author: Kalev Hantsoo

Publisher:

Published: 2017

Total Pages:

ISBN-13:

DOWNLOAD EBOOK

The Paleocene-Eocene Thermal Maximum (PETM), a transient greenhouse interval spurred by a large release of carbon to the ocean-atmosphere ca. 56 Ma, provides a geological point of comparison for anthropogenic carbon emission. However, while geochemical proxies and fossil assemblages offer insights into the continental shelf response to the PETM, existing ocean-atmosphere models of the PETM do not include accurate shelf and slope bathymetry. Model-proxy comparisons are of particular interest along continental margins, which are ecologically and biogeochemically critical environments.Here we present high-resolution simulations of the pre- and syn-PETM North Atlantic basin that include a resolved continental shelf along the eastern margin of North America in the Salisbury Embayment. We use the Regional Ocean Modeling System (ROMS), whose terrain-following coordinate system permits a new level of detail along continental margins while also capturing open ocean processes. Our models boundary conditions are drawn from existing models of the PETM. Under a carbon forcing consistent with a release of ~13000 PgC, the calcite saturation horizon rises to an average depth of 725 m in the North Atlantic. Concurrently, a regime of continental slope downwelling in the western North Atlantic weakens during PETM onset. On the continental shelf, benthic oxygen concentrations decrease by 32.5% with seasonal occurrence of moderate hypoxia, while average benthic calcite saturation declines from 3.2 to 1.9. These declines are primarily driven by oxic respiration spurred by an increase in primary production and a more efficient export flux to the shelf seafloor. Model results do not include river input to the continental shelf, which is hypothesized to have further reduced oxygen and carbonate ion concentrations in the benthic environment.