Multiple early Eocene hyperthermal events: Their lithologic expressions and environmental consequences

Nicolo, Micah John

January 2009

A gradual rise in Earth's surface temperature marks a transition from the late Paleocene to the early Eocene ca. 58-51 Ma. Paleocene/Eocene boundary (∼55.5 Ma) sediments deposited in the midst of this slow warming ubiquitously reveal evidence for a massive isotopically light carbon injection and an associated rapid but transient global warming event, or hyperthermal, that has been termed the Paleocene Eocene Thermal Maximum (PETM) and attributed to a carbon injection from multiple potential sources. The PETM has gained importance over the past two decades as a potential geologic analog to the modern anthropogenic carbon injection and climate change. However significant questions surrounding the nature of the carbon injection at the onset of the PETM remain. The Clarence River valley, located in the Marlborough region, South Island, New Zealand, contains a series of outcrops of lithified late Paleocene to early Eocene sediments originally deposited on a paleo-slope margin. Within these sections, the Lower Limestone Member of the Amuri Limestone Formation records the interval of interest. A Lower Limestone prominent recessed unit consisting of multiple marl-rich beds and recording a pronounced negative carbon isotopic excursion (CIE) marks the PETM at sections that have been bisected by tributaries to the Clarence River, including Mead Stream and Dee Stream. Here I detail and discuss Clarence valley Lower Limestone sections and relate these records to global trends with an emphasis on adding constraints to the PETM carbon injection. Specifically, I document the lithologic and carbon isotopic expression of the PETM and two younger paired sets of early Eocene events that, similar to the Mead Stream and Dee Stream PETM sections, reveal negative CIEs and expanded marl-rich units coincident to identical CIEs and condensed carbonate dissolution horizons in deep-sea sections. I further quantify the abundance of bioturbating macrofauna trace fossils through the PETM at both Mead Stream and Dee Stream and argue that New Zealand margin intermediate waters became hypoxic precisely coincident to the PETM carbon injection. In concert, these findings suggest a PETM carbon addition mechanism capable of both diminishing intermediate water dissolved oxygen and of repeated early Eocene injections. / U.S. National Science Foundation (NSF); Joint Oceanographic Institutions (JOI), Inc.

New Zealand

Eocene

Bioturbation

Hyperthermal events

Paleocene-Eocene thermal maximum

A Paleoclimate Modeling Experiment to Calculate the Soil Carbon Respiration Flux for the Paleocene-Eocene Thermal Maximum

Tracy, David M

01 January 2012

The Paleocene-Eocene Thermal Maximum (PETM) (55 million years ago) stands as the largest in a series of extreme warming (hyperthermal) climatic events, which are analogous to the modern day increase in greenhouse gas concentrations. Orbitally triggered (Lourens et al., 2005, Galeotti et al., 2010), the PETM is marked by a large (-3‰) carbon isotope excursion (CIE). Hypothesized to be methane driven, Zeebe et al., (2009) noted that a methane based release would only account for 3.5°C of warming. An isotopically heavier carbon, such as that of soil and C3 plants, has the potential to account for the warming and CIE (Zachos et al., 2005). During the early Eocene, high latitude surface temperatures created favorable conditions for the sequestration of terrestrial carbon. A large untapped terrestrial carbon reservoir, such as that within permafrost regions, contains the potential, if degraded, to account for the CIE as well as the global temperature increase observed during the PETM. Using an fully integrated climate model (GENESIS) with fully coupled vegetation model (BIOME4), we show that adequate conditions for permafrost growth and terrestrial carbon sequestration did exist during the lead up to the PETM. By calculating the flux of net primary production (NPP) and soil respiration (Rs), we demonstrate that the biodegradation of permafrost-based carbon reservoirs had the potential to drive the PETM. Furthermore, we show that the natural planetary response to unbalanced carbon reservoirs resulted in the terrestrial sequestration of atmospheric carbon via permafrost regeneration, yielding a vulnerable carbon reservoir for the subsequent hyperthermal.

Permafrost

Antarctica

Hyperthermal

Paleocene-Eocene Thermal Maximum

Net Primary Production

Soil Respiration

Atmospheric Sciences

Biogeochemistry

Climate

Geology

Hydrology

Organic Chemistry

Other Computer Sciences

Other Physical Sciences and Mathematics

Soil Science

Tectonics and Structure