Megadroughts and Intensified Terrestrial Flooding - Underrated Consequences of Early Eocene Hyperthermals?
Abstract
Here we present results of independent multi-proxy analyses of an Early Eocene sedimentary succession from the interior of the US, combining detailed sedimentologic and stratigraphic analyses with ichno-pedogenic analyses and stable carbon isotope analyses through 1000 m of river and lake deposits, across an area of ca 600 km2 in the Uinta Basin, Utah. This Early Eocene Climatic Optimum (ca 55.5-51.4 Myr ago) dataset is different from previously published terrestrial climate proxy analyses, in that we document the Palaeocene Eocene Thermal Maximum (PETM) as well as 6-8 post-PETM transient global warming events or hyperthermals by δ13Corg excursions, as well as river systems response to these events from the sedimentary record. Moreover, our dataset indicates that palaeosols and isotope values may in some cases only capture the long-term conditions, and are not able to reproduce the seasonality. We show that there are 6-8 Early Eocene hyperthermals that are climatically prominent enough to cause significant changes in the climate processes, as well as generate significant consequences to the river systems behaviour, recorded in the geological record. We show that in the continental interior of North America each of the Early Eocene transient global warming events or hyperthermals includes an onset period that reflects increased temperatures, weathering and sediment production, while the peaks of the hyperthermals indicate a shift to significantly intensified hydrological cycle with extreme conditions of prolonged megadroughts and short catastrophic terrestrial flooding episodes, followed by a recovery period. We demonstrate that only the PETM event exhibits a non-linear response to global warming, in that the system responded by alternations between increasing and decreasing seasonality during onset and offset, and has two distinct episodes of peak conditions. The PETM, and the H1, H2, I1, I2 events are distinct in both sedimentary and isotope record, whereas the youngest hyperthermals become successively more difficult to distinguish from the background conditions on both records. Thus, there is a long-term trend or transition from the most extreme conditions with prolonged megadroughts with seasonally dry river beds, and short catastrophic wet seasons with most extreme sediment production, erosion, deposition, and avulsion rates during the peak of the PETM, towards gradually milder conditions during the successive post-PETM hyperthermals. The peaks of the first three post-PETM hyperthermals (H1, H2, I1) are characterised by almost as severe conditions, as the PETM. The peaks of the following hyperthermals are successively less severe, but still reflect intensified seasonality, sediment production, deposition and avulsion rates. However, the peak conditions of these hyperthermals compare to the conditions during parts of onset or offset intervals of the PETM, rather than its peak.
- Publication:
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AGU Fall Meeting Abstracts
- Pub Date:
- December 2011
- Bibcode:
- 2011AGUFM.T13F2463P
- Keywords:
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- 0473 BIOGEOSCIENCES / Paleoclimatology and paleoceanography;
- 4948 PALEOCEANOGRAPHY / Paleocene/Eocene thermal maximum;
- 4321 NATURAL HAZARDS / Climate impact