Climate, carbon cycling and marine ecology during the Paleocene-Eocene Thermal Maximum

The Paleocene and Eocene are characterized by strong greenhouse climates. Atmospheric CO2 concentrations and global temperatures were much higher than today. The period from 60 to 50 million years ago (Ma) is marked by a gradual warming trend of ~8 ºC in the deep ocean. The interval from 56 to 50 Ma...

Full description

Bibliographic Details
Main Author: Frieling, J.
Other Authors: Marine palynology and palaeoceanography, DINOPRO: From Protist to Proxy, Dinoflagellates as signal carriers for climate and carbon cycling during past and present extreme climate transitions, Sluijs, Appy, Reichart, Gert-Jan
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: UU Dept. of Earth Sciences 2016
Subjects:
PETM
Paleocene
Eocene
temperature
biotic response
heat-stress
carbon-cycling
thermogenic methane
dinocyst paleoecology
Planktonic foraminifera
Siberia
Online Access:https://dspace.library.uu.nl/handle/1874/334859
Description
Summary:The Paleocene and Eocene are characterized by strong greenhouse climates. Atmospheric CO2 concentrations and global temperatures were much higher than today. The period from 60 to 50 million years ago (Ma) is marked by a gradual warming trend of ~8 ºC in the deep ocean. The interval from 56 to 50 Ma is further characterized by several transient perturbations of the carbon cycle. Essentially, these perturbations, or “hyperthermal” events mark phases of rapid (103 – 104 years) warming, associated with a drop in the stable carbon isotopic composition of the global exogenic carbon pool, which provides strong evidence that these warming events are related to rapid anomalous carbon input from a reservoir outside the global exogenic carbon cycle. The Paleocene–Eocene Thermal Maximum (PETM, ~56 Ma) is the hyperthermal with the largest magnitude of global warming (+4 ºC) and negative carbon isotope excursion (CIE; >3‰). Ample evidence for large-scale environmental perturbations and biotic migrations have been recorded, such as the quasi-global acme of the subtropical dinoflagellate cyst (dinocyst) genus Apectodinium. As global temperatures increased, the hydrological cycle accelerated and oceans experienced lower oxygen concentrations, both in bottom and surface waters. Several outstanding questions regarding carbon cycling, biotic response, spatial characteristics of temperature change during the PETM remain and are addressed in this thesis. A first record showing Northern Hemisphere sea surface temperature (SST) evolution across the late Paleocene to Early Eocene Climate Optimum (EECO) is presented, based on a record from Siberia. Both the short and long-term warming and presence and abundance of thermophilic biota, notably Apectodinium, are strongly associated. In contrast, two tropical sections in the equatorial Atlantic are marked by a large drop in diversity and number of dinocysts, as well as the absence of planktonic foraminifera, as SSTs rise >36 ºC during the PETM. Since temperature is the only variable ...

Similar Items